int main(){
int j,fa[4001],sec=INF,sectemp=INF,temp,n=scan(),i=n;
init();
dj(n);
for(j=0;j<=n;j++)fa[j]=father[j];
init();
do{
temp=value[i][fa[i]];
value[i][fa[i]]=INF;
value[fa[i]][i]=INF;
sectemp=dj(n);
init();
if(sectemp<sec)sec=sectemp;
value[i][fa[i]]=temp;
value[fa[i]][i]=temp;
i=fa[i];
}while(fa[i]!=0);
printf("%d",sec);
return 0;
}
int main(int argc, char *argv[])
{
setIO("sample");
n = gi;int m=gi;
for(int i = 1,u,v,w;i<=m;++i)u=gi,v=gi,w=gi,addedge(u,v,w);
dj(1,ds,ss,qs);
dj(n,dt,st,qt);
for(int i = 1;i<n;++i)
for(int j = hd[i];j;j=e[j].ne){
int k = e[j].v;
if(dt[k]+e[j].w == dt[i]){
fa[i] = k,e[j].fl = true;
addedge2(k,i);break;
}
}
static int qu[MN],bot;
qu[bot=1]=n;
for(int i = 1;i<=bot;++i){
int x = qu[i];
for(int j = hd2[x];j;j=e2[j].ne) qu[++bot]=e2[j].v;
}
for(int i = 1;i<=bot;++i){
int x = qu[i];
if(ds[x]+dt[x] == ds[n]) prt[x] = x;
else prt[x] = prt[fa[x]];
}
int ans = INF;
for(int i = 1;i<=tot;++i){
if(e[i].fl || ds[e[i].u]+e[i].w+dt[e[i].v]==ds[n])continue;
int u = prt[e[i].u],v = prt[e[i].v];
if(!u || !v || u==v || ds[u] > ds[v]) continue;
int tmp = ds[e[i].u]+e[i].w+dt[e[i].v];
ans = min(ans,tmp);
}
if(ans == INF )puts("-1");
else printf("%d\n",ans);
closeIO();
return EXIT_SUCCESS;
}
int main()
{
int start;
printf("\nDIJKSTRA ALGORITHM");
readgraph();
displaymat();
inittable();
printf("\nEnter the starting Vertex:");
scanf("%d",&start);
dj(start);
printf("\nfinal:");
displaytable();
getch();
return 0;
}
void
Assembly::addJacobianBlock(SparseMatrix<Number> & jacobian, DenseMatrix<Number> & jac_block, const std::vector<dof_id_type> & idof_indices, const std::vector<dof_id_type> & jdof_indices, Real scaling_factor)
{
if ((idof_indices.size() > 0) && (jdof_indices.size() > 0) && jac_block.n() && jac_block.m())
{
std::vector<dof_id_type> di(idof_indices);
std::vector<dof_id_type> dj(jdof_indices);
_dof_map.constrain_element_matrix(jac_block, di, dj, false);
if (scaling_factor != 1.0)
{
_tmp_Ke = jac_block;
_tmp_Ke *= scaling_factor;
jacobian.add_matrix(_tmp_Ke, di, dj);
}
else
jacobian.add_matrix(jac_block, di, dj);
}
}
void
Assembly::cacheJacobianBlock(DenseMatrix<Number> & jac_block, std::vector<dof_id_type> & idof_indices, std::vector<dof_id_type> & jdof_indices, Real scaling_factor)
{
if ((idof_indices.size() > 0) && (jdof_indices.size() > 0) && jac_block.n() && jac_block.m())
{
std::vector<dof_id_type> di(idof_indices);
std::vector<dof_id_type> dj(jdof_indices);
_dof_map.constrain_element_matrix(jac_block, di, dj, false);
if (scaling_factor != 1.0)
{
_tmp_Ke = jac_block;
_tmp_Ke *= scaling_factor;
for(unsigned int i=0; i<di.size(); i++)
for(unsigned int j=0; j<dj.size(); j++)
{
_cached_jacobian_values.push_back(_tmp_Ke(i, j));
_cached_jacobian_rows.push_back(di[i]);
_cached_jacobian_cols.push_back(dj[j]);
}
}
else
{
for(unsigned int i=0; i<di.size(); i++)
for(unsigned int j=0; j<dj.size(); j++)
{
_cached_jacobian_values.push_back(jac_block(i, j));
_cached_jacobian_rows.push_back(di[i]);
_cached_jacobian_cols.push_back(dj[j]);
}
}
}
jac_block.zero();
}
int SSL_SOCKET :: s_recv(char* b,int sz)
{
SecPkgContext_StreamSizes Sizes;
SECURITY_STATUS ss = 0;
ss = QueryContextAttributes(&hCtx,SECPKG_ATTR_STREAM_SIZES,&Sizes);
if (FAILED(ss))
return -1;
int TotalR = 0;
int pI = 0;
SecBuffer Buffers[5] = {0};
SecBuffer * pDataBuffer;
SecBuffer * pExtraBuffer;
Z<char> mmsg(Sizes.cbMaximumMessage*10);
if (PendingRecvDataSize)
{
if (sz <= PendingRecvDataSize)
{
memcpy(b,PendingRecvData,sz);
//
Z<char> dj(PendingRecvDataSize);
memcpy(dj,PendingRecvData,PendingRecvDataSize);
memcpy(PendingRecvData,dj + sz,PendingRecvDataSize - sz);
PendingRecvDataSize -= sz;
return sz;
}
// else , occupied already
memcpy(b,PendingRecvData,PendingRecvDataSize);
sz = PendingRecvDataSize;
PendingRecvDataSize = 0;
return sz;
}
for(;;)
{
unsigned int dwMessage = Sizes.cbMaximumMessage;
if (dwMessage > Sizes.cbMaximumMessage)
dwMessage = Sizes.cbMaximumMessage;
int rval = 0;
if (ExtraDataSize)
{
memcpy(mmsg + pI,ExtraData,ExtraDataSize);
pI += ExtraDataSize;
ExtraDataSize = 0;
}
else
{
rval = recv_p(mmsg + pI,dwMessage);
if (rval == 0 || rval == -1)
return rval;
pI += rval;
}
Buffers[0].pvBuffer = mmsg;
Buffers[0].cbBuffer = pI;
Buffers[0].BufferType = SECBUFFER_DATA;
Buffers[1].BufferType = SECBUFFER_EMPTY;
Buffers[2].BufferType = SECBUFFER_EMPTY;
Buffers[3].BufferType = SECBUFFER_EMPTY;
sbin.ulVersion = SECBUFFER_VERSION;
sbin.pBuffers = Buffers;
sbin.cBuffers = 4;
ss = DecryptMessage(&hCtx,&sbin,0,NULL);
if (ss == SEC_E_INCOMPLETE_MESSAGE)
continue;
if (ss != SEC_E_OK && ss != SEC_I_RENEGOTIATE && ss != SEC_I_CONTEXT_EXPIRED)
return -1;
pDataBuffer = NULL;
pExtraBuffer = NULL;
for (int i = 0; i < 4; i++)
{
if (pDataBuffer == NULL && Buffers[i].BufferType == SECBUFFER_DATA)
{
pDataBuffer = &Buffers[i];
}
if (pExtraBuffer == NULL && Buffers[i].BufferType == SECBUFFER_EXTRA)
{
pExtraBuffer = &Buffers[i];
}
}
if (pExtraBuffer)
{
ExtraDataSize = pExtraBuffer->cbBuffer;
ExtraData.Resize(ExtraDataSize + 10);
memcpy(ExtraData,pExtraBuffer->pvBuffer,ExtraDataSize);
pI = 0;
}
if (ss == SEC_I_RENEGOTIATE)
{
ss = ClientLoop();
if (FAILED(ss))
return -1;
}
if (pDataBuffer == 0)
break;
TotalR = pDataBuffer->cbBuffer;
if (TotalR <= sz)
{
memcpy(b,pDataBuffer->pvBuffer,TotalR);
}
else
{
TotalR = sz;
memcpy(b,pDataBuffer->pvBuffer,TotalR);
PendingRecvDataSize = pDataBuffer->cbBuffer - TotalR;
PendingRecvData.Resize(PendingRecvDataSize + 100);
PendingRecvData.clear();
memcpy(PendingRecvData,(char*)pDataBuffer->pvBuffer + TotalR,PendingRecvDataSize);
}
break;
}
return TotalR;
}
