зеркало из https://github.com/mozilla/gecko-dev.git
533 строки
18 KiB
C++
533 строки
18 KiB
C++
/* -*- Mode: C++; tab-width: 2; indent-tabs-mode: nil; c-basic-offset: 2 -*-
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*
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* This Source Code Form is subject to the terms of the Mozilla Public
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* License, v. 2.0. If a copy of the MPL was not distributed with this
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* file, You can obtain one at http://mozilla.org/MPL/2.0/. */
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#include "nsStreamConverterService.h"
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#include "nsIComponentRegistrar.h"
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#include "nsAutoPtr.h"
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#include "nsString.h"
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#include "nsAtom.h"
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#include "nsDeque.h"
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#include "nsIInputStream.h"
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#include "nsIStreamConverter.h"
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#include "nsICategoryManager.h"
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#include "nsXPCOM.h"
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#include "nsISupportsPrimitives.h"
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#include "nsCOMArray.h"
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#include "nsTArray.h"
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#include "nsServiceManagerUtils.h"
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#include "nsISimpleEnumerator.h"
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///////////////////////////////////////////////////////////////////
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// Breadth-First-Search (BFS) algorithm state classes and types.
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// Used to establish discovered verticies.
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enum BFScolors {white, gray, black};
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// BFS hashtable data class.
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struct BFSTableData {
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nsCString key;
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BFScolors color;
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int32_t distance;
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nsAutoPtr<nsCString> predecessor;
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explicit BFSTableData(const nsACString& aKey)
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: key(aKey), color(white), distance(-1)
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{
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}
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};
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////////////////////////////////////////////////////////////
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// nsISupports methods
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NS_IMPL_ISUPPORTS(nsStreamConverterService, nsIStreamConverterService)
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////////////////////////////////////////////////////////////
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// nsIStreamConverterService methods
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////////////////////////////////////////////////////////////
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// nsStreamConverterService methods
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// Builds the graph represented as an adjacency list (and built up in
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// memory using an nsObjectHashtable and nsCOMArray combination).
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//
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// :BuildGraph() consults the category manager for all stream converter
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// CONTRACTIDS then fills the adjacency list with edges.
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// An edge in this case is comprised of a FROM and TO MIME type combination.
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//
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// CONTRACTID format:
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// @mozilla.org/streamconv;1?from=text/html&to=text/plain
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// XXX curently we only handle a single from and to combo, we should repeat the
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// XXX registration process for any series of from-to combos.
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// XXX can use nsTokenizer for this.
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//
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nsresult
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nsStreamConverterService::BuildGraph() {
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nsresult rv;
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nsCOMPtr<nsICategoryManager> catmgr(do_GetService(NS_CATEGORYMANAGER_CONTRACTID, &rv));
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if (NS_FAILED(rv)) return rv;
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nsCOMPtr<nsISimpleEnumerator> entries;
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rv = catmgr->EnumerateCategory(NS_ISTREAMCONVERTER_KEY, getter_AddRefs(entries));
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if (NS_FAILED(rv)) return rv;
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// go through each entry to build the graph
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nsCOMPtr<nsISupports> supports;
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nsCOMPtr<nsISupportsCString> entry;
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rv = entries->GetNext(getter_AddRefs(supports));
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while (NS_SUCCEEDED(rv)) {
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entry = do_QueryInterface(supports);
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// get the entry string
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nsAutoCString entryString;
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rv = entry->GetData(entryString);
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if (NS_FAILED(rv)) return rv;
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// cobble the entry string w/ the converter key to produce a full contractID.
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nsAutoCString contractID(NS_ISTREAMCONVERTER_KEY);
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contractID.Append(entryString);
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// now we've got the CONTRACTID, let's parse it up.
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rv = AddAdjacency(contractID.get());
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if (NS_FAILED(rv)) return rv;
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rv = entries->GetNext(getter_AddRefs(supports));
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}
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return NS_OK;
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}
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// XXX currently you can not add the same adjacency (i.e. you can't have multiple
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// XXX stream converters registering to handle the same from-to combination. It's
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// XXX not programatically prohibited, it's just that results are un-predictable
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// XXX right now.
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nsresult
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nsStreamConverterService::AddAdjacency(const char *aContractID) {
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nsresult rv;
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// first parse out the FROM and TO MIME-types.
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nsAutoCString fromStr, toStr;
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rv = ParseFromTo(aContractID, fromStr, toStr);
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if (NS_FAILED(rv)) return rv;
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// Each MIME-type is a vertex in the graph, so first lets make sure
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// each MIME-type is represented as a key in our hashtable.
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nsTArray<RefPtr<nsAtom>>* fromEdges = mAdjacencyList.Get(fromStr);
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if (!fromEdges) {
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// There is no fromStr vertex, create one.
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fromEdges = new nsTArray<RefPtr<nsAtom>>();
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mAdjacencyList.Put(fromStr, fromEdges);
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}
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if (!mAdjacencyList.Get(toStr)) {
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// There is no toStr vertex, create one.
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mAdjacencyList.Put(toStr, new nsTArray<RefPtr<nsAtom>>());
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}
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// Now we know the FROM and TO types are represented as keys in the hashtable.
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// Let's "connect" the verticies, making an edge.
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RefPtr<nsAtom> vertex = NS_Atomize(toStr);
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if (!vertex) return NS_ERROR_OUT_OF_MEMORY;
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NS_ASSERTION(fromEdges, "something wrong in adjacency list construction");
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if (!fromEdges)
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return NS_ERROR_FAILURE;
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return fromEdges->AppendElement(vertex) ? NS_OK : NS_ERROR_FAILURE;
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}
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nsresult
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nsStreamConverterService::ParseFromTo(const char *aContractID, nsCString &aFromRes, nsCString &aToRes) {
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nsAutoCString ContractIDStr(aContractID);
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int32_t fromLoc = ContractIDStr.Find("from=");
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int32_t toLoc = ContractIDStr.Find("to=");
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if (-1 == fromLoc || -1 == toLoc ) return NS_ERROR_FAILURE;
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fromLoc = fromLoc + 5;
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toLoc = toLoc + 3;
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nsAutoCString fromStr, toStr;
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ContractIDStr.Mid(fromStr, fromLoc, toLoc - 4 - fromLoc);
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ContractIDStr.Mid(toStr, toLoc, ContractIDStr.Length() - toLoc);
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aFromRes.Assign(fromStr);
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aToRes.Assign(toStr);
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return NS_OK;
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}
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typedef nsClassHashtable<nsCStringHashKey, BFSTableData> BFSHashTable;
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// nsObjectHashtable enumerator functions.
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class CStreamConvDeallocator : public nsDequeFunctor {
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public:
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void operator()(void* anObject) override {
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nsCString *string = (nsCString*)anObject;
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delete string;
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}
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};
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// walks the graph using a breadth-first-search algorithm which generates a discovered
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// verticies tree. This tree is then walked up (from destination vertex, to origin vertex)
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// and each link in the chain is added to an nsStringArray. A direct lookup for the given
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// CONTRACTID should be made prior to calling this method in an attempt to find a direct
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// converter rather than walking the graph.
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nsresult
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nsStreamConverterService::FindConverter(const char *aContractID, nsTArray<nsCString> **aEdgeList) {
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nsresult rv;
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if (!aEdgeList) return NS_ERROR_NULL_POINTER;
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*aEdgeList = nullptr;
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// walk the graph in search of the appropriate converter.
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uint32_t vertexCount = mAdjacencyList.Count();
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if (0 >= vertexCount) return NS_ERROR_FAILURE;
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// Create a corresponding color table for each vertex in the graph.
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BFSHashTable lBFSTable;
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for (auto iter = mAdjacencyList.Iter(); !iter.Done(); iter.Next()) {
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const nsACString &key = iter.Key();
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MOZ_ASSERT(iter.UserData(), "no data in the table iteration");
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lBFSTable.Put(key, new BFSTableData(key));
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}
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NS_ASSERTION(lBFSTable.Count() == vertexCount, "strmconv BFS table init problem");
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// This is our source vertex; our starting point.
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nsAutoCString fromC, toC;
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rv = ParseFromTo(aContractID, fromC, toC);
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if (NS_FAILED(rv)) return rv;
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BFSTableData *data = lBFSTable.Get(fromC);
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if (!data) {
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return NS_ERROR_FAILURE;
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}
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data->color = gray;
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data->distance = 0;
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auto *dtorFunc = new CStreamConvDeallocator();
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nsDeque grayQ(dtorFunc);
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// Now generate the shortest path tree.
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grayQ.Push(new nsCString(fromC));
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while (0 < grayQ.GetSize()) {
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nsCString *currentHead = (nsCString*)grayQ.PeekFront();
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nsTArray<RefPtr<nsAtom>>* data2 = mAdjacencyList.Get(*currentHead);
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if (!data2) return NS_ERROR_FAILURE;
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// Get the state of the current head to calculate the distance of each
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// reachable vertex in the loop.
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BFSTableData *headVertexState = lBFSTable.Get(*currentHead);
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if (!headVertexState) return NS_ERROR_FAILURE;
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int32_t edgeCount = data2->Length();
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for (int32_t i = 0; i < edgeCount; i++) {
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nsAtom* curVertexAtom = data2->ElementAt(i);
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auto *curVertex = new nsCString();
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curVertexAtom->ToUTF8String(*curVertex);
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BFSTableData *curVertexState = lBFSTable.Get(*curVertex);
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if (!curVertexState) {
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delete curVertex;
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return NS_ERROR_FAILURE;
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}
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if (white == curVertexState->color) {
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curVertexState->color = gray;
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curVertexState->distance = headVertexState->distance + 1;
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curVertexState->predecessor = new nsCString(*currentHead);
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grayQ.Push(curVertex);
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} else {
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delete curVertex; // if this vertex has already been discovered, we don't want
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// to leak it. (non-discovered vertex's get cleaned up when
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// they're popped).
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}
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}
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headVertexState->color = black;
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nsCString *cur = (nsCString*)grayQ.PopFront();
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delete cur;
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cur = nullptr;
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}
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// The shortest path (if any) has been generated and is represented by the chain of
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// BFSTableData->predecessor keys. Start at the bottom and work our way up.
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// first parse out the FROM and TO MIME-types being registered.
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nsAutoCString fromStr, toMIMEType;
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rv = ParseFromTo(aContractID, fromStr, toMIMEType);
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if (NS_FAILED(rv)) return rv;
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// get the root CONTRACTID
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nsAutoCString ContractIDPrefix(NS_ISTREAMCONVERTER_KEY);
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auto *shortestPath = new nsTArray<nsCString>();
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data = lBFSTable.Get(toMIMEType);
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if (!data) {
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// If this vertex isn't in the BFSTable, then no-one has registered for it,
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// therefore we can't do the conversion.
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delete shortestPath;
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return NS_ERROR_FAILURE;
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}
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while (data) {
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if (fromStr.Equals(data->key)) {
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// found it. We're done here.
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*aEdgeList = shortestPath;
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return NS_OK;
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}
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// reconstruct the CONTRACTID.
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// Get the predecessor.
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if (!data->predecessor) break; // no predecessor
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BFSTableData *predecessorData = lBFSTable.Get(*data->predecessor);
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if (!predecessorData) break; // no predecessor, chain doesn't exist.
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// build out the CONTRACTID.
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nsAutoCString newContractID(ContractIDPrefix);
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newContractID.AppendLiteral("?from=");
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newContractID.Append(predecessorData->key);
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newContractID.AppendLiteral("&to=");
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newContractID.Append(data->key);
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// Add this CONTRACTID to the chain.
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rv = shortestPath->AppendElement(newContractID) ? NS_OK : NS_ERROR_FAILURE; // XXX this method incorrectly returns a bool
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NS_ASSERTION(NS_SUCCEEDED(rv), "AppendElement failed");
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// move up the tree.
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data = predecessorData;
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}
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delete shortestPath;
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return NS_ERROR_FAILURE; // couldn't find a stream converter or chain.
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}
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/////////////////////////////////////////////////////
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// nsIStreamConverterService methods
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NS_IMETHODIMP
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nsStreamConverterService::CanConvert(const char* aFromType,
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const char* aToType,
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bool* _retval) {
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nsCOMPtr<nsIComponentRegistrar> reg;
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nsresult rv = NS_GetComponentRegistrar(getter_AddRefs(reg));
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if (NS_FAILED(rv))
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return rv;
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nsAutoCString contractID;
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contractID.AssignLiteral(NS_ISTREAMCONVERTER_KEY "?from=");
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contractID.Append(aFromType);
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contractID.AppendLiteral("&to=");
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contractID.Append(aToType);
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// See if we have a direct match
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rv = reg->IsContractIDRegistered(contractID.get(), _retval);
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if (NS_FAILED(rv))
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return rv;
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if (*_retval)
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return NS_OK;
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// Otherwise try the graph.
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rv = BuildGraph();
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if (NS_FAILED(rv))
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return rv;
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nsTArray<nsCString> *converterChain = nullptr;
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rv = FindConverter(contractID.get(), &converterChain);
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*_retval = NS_SUCCEEDED(rv);
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delete converterChain;
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return NS_OK;
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}
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NS_IMETHODIMP
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nsStreamConverterService::Convert(nsIInputStream *aFromStream,
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const char *aFromType,
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const char *aToType,
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nsISupports *aContext,
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nsIInputStream **_retval) {
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if (!aFromStream || !aFromType || !aToType || !_retval) return NS_ERROR_NULL_POINTER;
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nsresult rv;
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// first determine whether we can even handle this conversion
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// build a CONTRACTID
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nsAutoCString contractID;
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contractID.AssignLiteral(NS_ISTREAMCONVERTER_KEY "?from=");
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contractID.Append(aFromType);
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contractID.AppendLiteral("&to=");
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contractID.Append(aToType);
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const char *cContractID = contractID.get();
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nsCOMPtr<nsIStreamConverter> converter(do_CreateInstance(cContractID, &rv));
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if (NS_FAILED(rv)) {
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// couldn't go direct, let's try walking the graph of converters.
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rv = BuildGraph();
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if (NS_FAILED(rv)) return rv;
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nsTArray<nsCString> *converterChain = nullptr;
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rv = FindConverter(cContractID, &converterChain);
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if (NS_FAILED(rv)) {
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// can't make this conversion.
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// XXX should have a more descriptive error code.
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return NS_ERROR_FAILURE;
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}
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int32_t edgeCount = int32_t(converterChain->Length());
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NS_ASSERTION(edgeCount > 0, "findConverter should have failed");
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// convert the stream using each edge of the graph as a step.
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// this is our stream conversion traversal.
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nsCOMPtr<nsIInputStream> dataToConvert = aFromStream;
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nsCOMPtr<nsIInputStream> convertedData;
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for (int32_t i = edgeCount-1; i >= 0; i--) {
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const char *lContractID = converterChain->ElementAt(i).get();
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converter = do_CreateInstance(lContractID, &rv);
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if (NS_FAILED(rv)) {
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delete converterChain;
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return rv;
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}
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nsAutoCString fromStr, toStr;
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rv = ParseFromTo(lContractID, fromStr, toStr);
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if (NS_FAILED(rv)) {
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delete converterChain;
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return rv;
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}
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rv = converter->Convert(dataToConvert, fromStr.get(), toStr.get(), aContext, getter_AddRefs(convertedData));
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dataToConvert = convertedData;
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if (NS_FAILED(rv)) {
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delete converterChain;
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return rv;
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}
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}
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delete converterChain;
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convertedData.forget(_retval);
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} else {
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// we're going direct.
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rv = converter->Convert(aFromStream, aFromType, aToType, aContext, _retval);
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}
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return rv;
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}
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NS_IMETHODIMP
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nsStreamConverterService::AsyncConvertData(const char *aFromType,
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const char *aToType,
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nsIStreamListener *aListener,
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nsISupports *aContext,
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nsIStreamListener **_retval) {
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if (!aFromType || !aToType || !aListener || !_retval) return NS_ERROR_NULL_POINTER;
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nsresult rv;
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// first determine whether we can even handle this conversion
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// build a CONTRACTID
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nsAutoCString contractID;
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contractID.AssignLiteral(NS_ISTREAMCONVERTER_KEY "?from=");
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contractID.Append(aFromType);
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contractID.AppendLiteral("&to=");
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contractID.Append(aToType);
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const char *cContractID = contractID.get();
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nsCOMPtr<nsIStreamConverter> listener(do_CreateInstance(cContractID, &rv));
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if (NS_FAILED(rv)) {
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// couldn't go direct, let's try walking the graph of converters.
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rv = BuildGraph();
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if (NS_FAILED(rv)) return rv;
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nsTArray<nsCString> *converterChain = nullptr;
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rv = FindConverter(cContractID, &converterChain);
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if (NS_FAILED(rv)) {
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// can't make this conversion.
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// XXX should have a more descriptive error code.
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return NS_ERROR_FAILURE;
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}
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// aListener is the listener that wants the final, converted, data.
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// we initialize finalListener w/ aListener so it gets put at the
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// tail end of the chain, which in the loop below, means the *first*
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// converter created.
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nsCOMPtr<nsIStreamListener> finalListener = aListener;
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// convert the stream using each edge of the graph as a step.
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// this is our stream conversion traversal.
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int32_t edgeCount = int32_t(converterChain->Length());
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NS_ASSERTION(edgeCount > 0, "findConverter should have failed");
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for (int i = 0; i < edgeCount; i++) {
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const char *lContractID = converterChain->ElementAt(i).get();
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// create the converter for this from/to pair
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nsCOMPtr<nsIStreamConverter> converter(do_CreateInstance(lContractID));
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NS_ASSERTION(converter, "graph construction problem, built a contractid that wasn't registered");
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nsAutoCString fromStr, toStr;
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rv = ParseFromTo(lContractID, fromStr, toStr);
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if (NS_FAILED(rv)) {
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delete converterChain;
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return rv;
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}
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// connect the converter w/ the listener that should get the converted data.
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rv = converter->AsyncConvertData(fromStr.get(), toStr.get(), finalListener, aContext);
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if (NS_FAILED(rv)) {
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delete converterChain;
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return rv;
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}
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// the last iteration of this loop will result in finalListener
|
|
// pointing to the converter that "starts" the conversion chain.
|
|
// this converter's "from" type is the original "from" type. Prior
|
|
// to the last iteration, finalListener will continuously be wedged
|
|
// into the next listener in the chain, then be updated.
|
|
finalListener = converter;
|
|
}
|
|
delete converterChain;
|
|
// return the first listener in the chain.
|
|
finalListener.forget(_retval);
|
|
} else {
|
|
// we're going direct.
|
|
rv = listener->AsyncConvertData(aFromType, aToType, aListener, aContext);
|
|
listener.forget(_retval);
|
|
}
|
|
|
|
return rv;
|
|
|
|
}
|
|
|
|
nsresult
|
|
NS_NewStreamConv(nsStreamConverterService** aStreamConv)
|
|
{
|
|
MOZ_ASSERT(aStreamConv != nullptr, "null ptr");
|
|
if (!aStreamConv) return NS_ERROR_NULL_POINTER;
|
|
|
|
*aStreamConv = new nsStreamConverterService();
|
|
NS_ADDREF(*aStreamConv);
|
|
|
|
return NS_OK;
|
|
}
|