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Diffstat (limited to 'libnetdata/libjudy/src/JudyL/JudyLByCount.c')
-rw-r--r-- | libnetdata/libjudy/src/JudyL/JudyLByCount.c | 954 |
1 files changed, 954 insertions, 0 deletions
diff --git a/libnetdata/libjudy/src/JudyL/JudyLByCount.c b/libnetdata/libjudy/src/JudyL/JudyLByCount.c new file mode 100644 index 00000000..c5a00479 --- /dev/null +++ b/libnetdata/libjudy/src/JudyL/JudyLByCount.c @@ -0,0 +1,954 @@ +// Copyright (C) 2000 - 2002 Hewlett-Packard Company +// +// This program is free software; you can redistribute it and/or modify it +// under the term of the GNU Lesser 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 Lesser General Public License +// for more details. +// +// You should have received a copy of the GNU Lesser General Public License +// along with this program; if not, write to the Free Software Foundation, +// Inc., 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA +// _________________ + +// @(#) $Revision: 4.28 $ $Source: /judy/src/JudyCommon/JudyByCount.c $ +// +// Judy*ByCount() function for Judy1 and JudyL. +// Compile with one of -DJUDY1 or -DJUDYL. +// +// Compile with -DNOSMARTJBB, -DNOSMARTJBU, and/or -DNOSMARTJLB to build a +// version with cache line optimizations deleted, for testing. +// +// Judy*ByCount() is a conceptual although not literal inverse of Judy*Count(). +// Judy*Count() takes a pair of Indexes, and allows finding the ordinal of a +// given Index (that is, its position in the list of valid indexes from the +// beginning) as a degenerate case, because in general the count between two +// Indexes, inclusive, is not always just the difference in their ordinals. +// However, it suffices for Judy*ByCount() to simply be an ordinal-to-Index +// mapper. +// +// Note: Like Judy*Count(), this code must "count sideways" in branches, which +// can result in a lot of cache line fills. However, unlike Judy*Count(), this +// code does not receive a specific Index, hence digit, where to start in each +// branch, so it cant accurately calculate cache line fills required in each +// direction. The best it can do is an approximation based on the total +// population of the expanse (pop1 from Pjp) and the ordinal of the target +// Index (see SETOFFSET()) within the expanse. +// +// Compile with -DSMARTMETRICS to obtain global variables containing smart +// cache line metrics. Note: Dont turn this on simultaneously for this file +// and JudyCount.c because they export the same globals. +// **************************************************************************** + +#if (! (defined(JUDY1) || defined(JUDYL))) +#error: One of -DJUDY1 or -DJUDYL must be specified. +#endif + +#ifdef JUDY1 +#include "Judy1.h" +#else +#include "JudyL.h" +#endif + +#include "JudyPrivate1L.h" + +// These are imported from JudyCount.c: +// +// TBD: Should this be in common code? Exported from a header file? + +#ifdef JUDY1 +extern Word_t j__udy1JPPop1(const Pjp_t Pjp); +#define j__udyJPPop1 j__udy1JPPop1 +#else +extern Word_t j__udyLJPPop1(const Pjp_t Pjp); +#define j__udyJPPop1 j__udyLJPPop1 +#endif + +// Avoid duplicate symbols since this file is multi-compiled: + +#ifdef SMARTMETRICS +#ifdef JUDY1 +Word_t jbb_upward = 0; // counts of directions taken: +Word_t jbb_downward = 0; +Word_t jbu_upward = 0; +Word_t jbu_downward = 0; +Word_t jlb_upward = 0; +Word_t jlb_downward = 0; +#else +extern Word_t jbb_upward; +extern Word_t jbb_downward; +extern Word_t jbu_upward; +extern Word_t jbu_downward; +extern Word_t jlb_upward; +extern Word_t jlb_downward; +#endif +#endif + + +// **************************************************************************** +// J U D Y 1 B Y C O U N T +// J U D Y L B Y C O U N T +// +// See the manual entry. + +#ifdef JUDY1 +FUNCTION int Judy1ByCount +#else +FUNCTION PPvoid_t JudyLByCount +#endif + ( + Pcvoid_t PArray, // root pointer to first branch/leaf in SM. + Word_t Count, // ordinal of Index to find, 1..MAX. + Word_t * PIndex, // to return found Index. + PJError_t PJError // optional, for returning error info. + ) +{ + Word_t Count0; // Count, base-0, to match pop0. + Word_t state; // current state in SM. + Word_t pop1; // of current branch or leaf, or of expanse. + Word_t pop1lower; // pop1 of expanses (JPs) below that for Count. + Word_t digit; // current word in branch. + Word_t jpcount; // JPs in a BranchB subexpanse. + long jpnum; // JP number in a branch (base 0). + long subexp; // for stepping through layer 1 (subexpanses). + int offset; // index ordinal within a leaf, base 0. + + Pjp_t Pjp; // current JP in branch. + Pjll_t Pjll; // current Judy linear leaf. + + +// CHECK FOR EMPTY ARRAY OR NULL PINDEX: + + if (PArray == (Pvoid_t) NULL) JU_RET_NOTFOUND; + + if (PIndex == (PWord_t) NULL) + { + JU_SET_ERRNO(PJError, JU_ERRNO_NULLPINDEX); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + +// Convert Count to Count0; assume special case of Count = 0 maps to ~0, as +// desired, to represent the last index in a full array: +// +// Note: Think of Count0 as a reliable "number of Indexes below the target." + + Count0 = Count - 1; + assert((Count || Count0 == ~0)); // ensure CPU is sane about 0 - 1. + pop1lower = 0; + + if (JU_LEAFW_POP0(PArray) < cJU_LEAFW_MAXPOP1) // must be a LEAFW + { + Pjlw_t Pjlw = P_JLW(PArray); // first word of leaf. + + if (Count0 > Pjlw[0]) JU_RET_NOTFOUND; // too high. + + *PIndex = Pjlw[Count]; // Index, base 1. + + JU_RET_FOUND_LEAFW(Pjlw, Pjlw[0] + 1, Count0); + } + else + { + Pjpm_t Pjpm = P_JPM(PArray); + + if (Count0 > (Pjpm->jpm_Pop0)) JU_RET_NOTFOUND; // too high. + + Pjp = &(Pjpm->jpm_JP); + pop1 = (Pjpm->jpm_Pop0) + 1; + +// goto SMByCount; + } + +// COMMON CODE: +// +// Prepare to handle a root-level or lower-level branch: Save the current +// state, obtain the total population for the branch in a state-dependent way, +// and then branch to common code for multiple cases. +// +// For root-level branches, the state is always cJU_ROOTSTATE, and the array +// population must already be set in pop1; it is not available in jp_DcdPopO. +// +// Note: The total population is only needed in cases where the common code +// "counts down" instead of up to minimize cache line fills. However, its +// available cheaply, and its better to do it with a constant shift (constant +// state value) instead of a variable shift later "when needed". + +#define PREPB_ROOT(Next) \ + state = cJU_ROOTSTATE; \ + goto Next + +// Use PREPB_DCD() to first copy the Dcd bytes to *PIndex if there are any +// (only if state < cJU_ROOTSTATE - 1): + +#define PREPB_DCD(Pjp,cState,Next) \ + JU_SETDCD(*PIndex, Pjp, cState); \ + PREPB((Pjp), cState, Next) + +#define PREPB(Pjp,cState,Next) \ + state = (cState); \ + pop1 = JU_JPBRANCH_POP0(Pjp, (cState)) + 1; \ + goto Next + +// Calculate whether the ordinal of an Index within a given expanse falls in +// the lower or upper half of the expanses population, taking care with +// unsigned math and boundary conditions: +// +// Note: Assume the ordinal falls within the expanses population, that is, +// 0 < (Count - Pop1lower) <= Pop1exp (assuming infinite math). +// +// Note: If the ordinal is the middle element, it doesnt matter whether +// LOWERHALF() is TRUE or FALSE. + +#define LOWERHALF(Count0,Pop1lower,Pop1exp) \ + (((Count0) - (Pop1lower)) < ((Pop1exp) / 2)) + +// Calculate the (signed) offset within a leaf to the desired ordinal (Count - +// Pop1lower; offset is one less), and optionally ensure its in range: + +#define SETOFFSET(Offset,Count0,Pop1lower,Pjp) \ + (Offset) = (Count0) - (Pop1lower); \ + assert((Offset) >= 0); \ + assert((Offset) <= JU_JPLEAF_POP0(Pjp)) + +// Variations for immediate indexes, with and without pop1-specific assertions: + +#define SETOFFSET_IMM_CK(Offset,Count0,Pop1lower,cPop1) \ + (Offset) = (Count0) - (Pop1lower); \ + assert((Offset) >= 0); \ + assert((Offset) < (cPop1)) + +#define SETOFFSET_IMM(Offset,Count0,Pop1lower) \ + (Offset) = (Count0) - (Pop1lower) + + +// STATE MACHINE -- TRAVERSE TREE: +// +// In branches, look for the expanse (digit), if any, where the total pop1 +// below or at that expanse would meet or exceed Count, meaning the Index must +// be in this expanse. + +SMByCount: // return here for next branch/leaf. + + switch (JU_JPTYPE(Pjp)) + { + + +// ---------------------------------------------------------------------------- +// LINEAR BRANCH; count populations in JPs in the JBL upwards until finding the +// expanse (digit) containing Count, and "recurse". +// +// Note: There are no null JPs in a JBL; watch out for pop1 == 0. +// +// Note: A JBL should always fit in one cache line => no need to count up +// versus down to save cache line fills. +// +// TBD: The previous is no longer true. Consider enhancing this code to count +// up/down, but it can wait for a later tuning phase. In the meantime, PREPB() +// sets pop1 for the whole array, but that value is not used here. 001215: +// Maybe its true again? + + case cJU_JPBRANCH_L2: PREPB_DCD(Pjp, 2, BranchL); +#ifndef JU_64BIT + case cJU_JPBRANCH_L3: PREPB( Pjp, 3, BranchL); +#else + case cJU_JPBRANCH_L3: PREPB_DCD(Pjp, 3, BranchL); + case cJU_JPBRANCH_L4: PREPB_DCD(Pjp, 4, BranchL); + case cJU_JPBRANCH_L5: PREPB_DCD(Pjp, 5, BranchL); + case cJU_JPBRANCH_L6: PREPB_DCD(Pjp, 6, BranchL); + case cJU_JPBRANCH_L7: PREPB( Pjp, 7, BranchL); +#endif + case cJU_JPBRANCH_L: PREPB_ROOT( BranchL); + { + Pjbl_t Pjbl; + +// Common code (state-independent) for all cases of linear branches: + +BranchL: + Pjbl = P_JBL(Pjp->jp_Addr); + + for (jpnum = 0; jpnum < (Pjbl->jbl_NumJPs); ++jpnum) + { + if ((pop1 = j__udyJPPop1((Pjbl->jbl_jp) + jpnum)) + == cJU_ALLONES) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + assert(pop1 != 0); + +// Warning: pop1lower and pop1 are unsigned, so do not subtract 1 and compare +// >=, but instead use the following expression: + + if (pop1lower + pop1 > Count0) // Index is in this expanse. + { + JU_SETDIGIT(*PIndex, Pjbl->jbl_Expanse[jpnum], state); + Pjp = (Pjbl->jbl_jp) + jpnum; + goto SMByCount; // look under this expanse. + } + + pop1lower += pop1; // add this JPs pop1. + } + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // should never get here. + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // case cJU_JPBRANCH_L + + +// ---------------------------------------------------------------------------- +// BITMAP BRANCH; count populations in JPs in the JBB upwards or downwards +// until finding the expanse (digit) containing Count, and "recurse". +// +// Note: There are no null JPs in a JBB; watch out for pop1 == 0. + + case cJU_JPBRANCH_B2: PREPB_DCD(Pjp, 2, BranchB); +#ifndef JU_64BIT + case cJU_JPBRANCH_B3: PREPB( Pjp, 3, BranchB); +#else + case cJU_JPBRANCH_B3: PREPB_DCD(Pjp, 3, BranchB); + case cJU_JPBRANCH_B4: PREPB_DCD(Pjp, 4, BranchB); + case cJU_JPBRANCH_B5: PREPB_DCD(Pjp, 5, BranchB); + case cJU_JPBRANCH_B6: PREPB_DCD(Pjp, 6, BranchB); + case cJU_JPBRANCH_B7: PREPB( Pjp, 7, BranchB); +#endif + case cJU_JPBRANCH_B: PREPB_ROOT( BranchB); + { + Pjbb_t Pjbb; + +// Common code (state-independent) for all cases of bitmap branches: + +BranchB: + Pjbb = P_JBB(Pjp->jp_Addr); + +// Shorthand for one subexpanse in a bitmap and for one JP in a bitmap branch: +// +// Note: BMPJP0 exists separately to support assertions. + +#define BMPJP0(Subexp) (P_JP(JU_JBB_PJP(Pjbb, Subexp))) +#define BMPJP(Subexp,JPnum) (BMPJP0(Subexp) + (JPnum)) + + +// Common code for descending through a JP: +// +// Determine the digit for the expanse and save it in *PIndex; then "recurse". + +#define JBB_FOUNDEXPANSE \ + { \ + JU_BITMAPDIGITB(digit, subexp, JU_JBB_BITMAP(Pjbb,subexp), jpnum); \ + JU_SETDIGIT(*PIndex, digit, state); \ + Pjp = BMPJP(subexp, jpnum); \ + goto SMByCount; \ + } + + +#ifndef NOSMARTJBB // enable to turn off smart code for comparison purposes. + +// FIGURE OUT WHICH DIRECTION CAUSES FEWER CACHE LINE FILLS; adding the pop1s +// in JPs upwards, or subtracting the pop1s in JPs downwards: +// +// See header comments about limitations of this for Judy*ByCount(). + +#endif + +// COUNT UPWARD, adding each "below" JPs pop1: + +#ifndef NOSMARTJBB // enable to turn off smart code for comparison purposes. + + if (LOWERHALF(Count0, pop1lower, pop1)) + { +#endif +#ifdef SMARTMETRICS + ++jbb_upward; +#endif + for (subexp = 0; subexp < cJU_NUMSUBEXPB; ++subexp) + { + if ((jpcount = j__udyCountBitsB(JU_JBB_BITMAP(Pjbb,subexp))) + && (BMPJP0(subexp) == (Pjp_t) NULL)) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // null ptr. + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + +// Note: An empty subexpanse (jpcount == 0) is handled "for free": + + for (jpnum = 0; jpnum < jpcount; ++jpnum) + { + if ((pop1 = j__udyJPPop1(BMPJP(subexp, jpnum))) + == cJU_ALLONES) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + assert(pop1 != 0); + +// Warning: pop1lower and pop1 are unsigned, see earlier comment: + + if (pop1lower + pop1 > Count0) + JBB_FOUNDEXPANSE; // Index is in this expanse. + + pop1lower += pop1; // add this JPs pop1. + } + } +#ifndef NOSMARTJBB // enable to turn off smart code for comparison purposes. + } + + +// COUNT DOWNWARD, subtracting each "above" JPs pop1 from the whole expanses +// pop1: + + else + { +#ifdef SMARTMETRICS + ++jbb_downward; +#endif + pop1lower += pop1; // add whole branch to start. + + for (subexp = cJU_NUMSUBEXPB - 1; subexp >= 0; --subexp) + { + if ((jpcount = j__udyCountBitsB(JU_JBB_BITMAP(Pjbb, subexp))) + && (BMPJP0(subexp) == (Pjp_t) NULL)) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // null ptr. + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + +// Note: An empty subexpanse (jpcount == 0) is handled "for free": + + for (jpnum = jpcount - 1; jpnum >= 0; --jpnum) + { + if ((pop1 = j__udyJPPop1(BMPJP(subexp, jpnum))) + == cJU_ALLONES) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + assert(pop1 != 0); + +// Warning: pop1lower and pop1 are unsigned, see earlier comment: + + pop1lower -= pop1; + +// Beware unsigned math problems: + + if ((pop1lower == 0) || (pop1lower - 1 < Count0)) + JBB_FOUNDEXPANSE; // Index is in this expanse. + } + } + } +#endif // NOSMARTJBB + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // should never get here. + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // case cJU_JPBRANCH_B + + +// ---------------------------------------------------------------------------- +// UNCOMPRESSED BRANCH; count populations in JPs in the JBU upwards or +// downwards until finding the expanse (digit) containing Count, and "recurse". + + case cJU_JPBRANCH_U2: PREPB_DCD(Pjp, 2, BranchU); +#ifndef JU_64BIT + case cJU_JPBRANCH_U3: PREPB( Pjp, 3, BranchU); +#else + case cJU_JPBRANCH_U3: PREPB_DCD(Pjp, 3, BranchU); + case cJU_JPBRANCH_U4: PREPB_DCD(Pjp, 4, BranchU); + case cJU_JPBRANCH_U5: PREPB_DCD(Pjp, 5, BranchU); + case cJU_JPBRANCH_U6: PREPB_DCD(Pjp, 6, BranchU); + case cJU_JPBRANCH_U7: PREPB( Pjp, 7, BranchU); +#endif + case cJU_JPBRANCH_U: PREPB_ROOT( BranchU); + { + Pjbu_t Pjbu; + +// Common code (state-independent) for all cases of uncompressed branches: + +BranchU: + Pjbu = P_JBU(Pjp->jp_Addr); + +// Common code for descending through a JP: +// +// Save the digit for the expanse in *PIndex, then "recurse". + +#define JBU_FOUNDEXPANSE \ + { \ + JU_SETDIGIT(*PIndex, jpnum, state); \ + Pjp = (Pjbu->jbu_jp) + jpnum; \ + goto SMByCount; \ + } + + +#ifndef NOSMARTJBU // enable to turn off smart code for comparison purposes. + +// FIGURE OUT WHICH DIRECTION CAUSES FEWER CACHE LINE FILLS; adding the pop1s +// in JPs upwards, or subtracting the pop1s in JPs downwards: +// +// See header comments about limitations of this for Judy*ByCount(). + +#endif + +// COUNT UPWARD, simply adding the pop1 of each JP: + +#ifndef NOSMARTJBU // enable to turn off smart code for comparison purposes. + + if (LOWERHALF(Count0, pop1lower, pop1)) + { +#endif +#ifdef SMARTMETRICS + ++jbu_upward; +#endif + + for (jpnum = 0; jpnum < cJU_BRANCHUNUMJPS; ++jpnum) + { + // shortcut, save a function call: + + if ((Pjbu->jbu_jp[jpnum].jp_Type) <= cJU_JPNULLMAX) + continue; + + if ((pop1 = j__udyJPPop1((Pjbu->jbu_jp) + jpnum)) + == cJU_ALLONES) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + assert(pop1 != 0); + +// Warning: pop1lower and pop1 are unsigned, see earlier comment: + + if (pop1lower + pop1 > Count0) + JBU_FOUNDEXPANSE; // Index is in this expanse. + + pop1lower += pop1; // add this JPs pop1. + } +#ifndef NOSMARTJBU // enable to turn off smart code for comparison purposes. + } + + +// COUNT DOWNWARD, subtracting the pop1 of each JP above from the whole +// expanses pop1: + + else + { +#ifdef SMARTMETRICS + ++jbu_downward; +#endif + pop1lower += pop1; // add whole branch to start. + + for (jpnum = cJU_BRANCHUNUMJPS - 1; jpnum >= 0; --jpnum) + { + // shortcut, save a function call: + + if ((Pjbu->jbu_jp[jpnum].jp_Type) <= cJU_JPNULLMAX) + continue; + + if ((pop1 = j__udyJPPop1(Pjbu->jbu_jp + jpnum)) + == cJU_ALLONES) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + assert(pop1 != 0); + +// Warning: pop1lower and pop1 are unsigned, see earlier comment: + + pop1lower -= pop1; + +// Beware unsigned math problems: + + if ((pop1lower == 0) || (pop1lower - 1 < Count0)) + JBU_FOUNDEXPANSE; // Index is in this expanse. + } + } +#endif // NOSMARTJBU + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // should never get here. + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // case cJU_JPBRANCH_U + +// ---------------------------------------------------------------------------- +// LINEAR LEAF: +// +// Return the Index at the proper ordinal (see SETOFFSET()) in the leaf. First +// copy Dcd bytes, if there are any (only if state < cJU_ROOTSTATE - 1), to +// *PIndex. +// +// Note: The preceding branch traversal code MIGHT set pop1 for this expanse +// (linear leaf) as a side-effect, but dont depend on that (for JUDYL, which +// is the only cases that need it anyway). + +#define PREPL_DCD(cState) \ + JU_SETDCD(*PIndex, Pjp, cState); \ + PREPL + +#ifdef JUDY1 +#define PREPL_SETPOP1 // not needed in any cases. +#else +#define PREPL_SETPOP1 pop1 = JU_JPLEAF_POP0(Pjp) + 1 +#endif + +#define PREPL \ + Pjll = P_JLL(Pjp->jp_Addr); \ + PREPL_SETPOP1; \ + SETOFFSET(offset, Count0, pop1lower, Pjp) + +#if (defined(JUDYL) || (! defined(JU_64BIT))) + case cJU_JPLEAF1: + + PREPL_DCD(1); + JU_SETDIGIT1(*PIndex, ((uint8_t *) Pjll)[offset]); + JU_RET_FOUND_LEAF1(Pjll, pop1, offset); +#endif + + case cJU_JPLEAF2: + + PREPL_DCD(2); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(2))) + | ((uint16_t *) Pjll)[offset]; + JU_RET_FOUND_LEAF2(Pjll, pop1, offset); + +#ifndef JU_64BIT + case cJU_JPLEAF3: + { + Word_t lsb; + PREPL; + JU_COPY3_PINDEX_TO_LONG(lsb, ((uint8_t *) Pjll) + (3 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(3))) | lsb; + JU_RET_FOUND_LEAF3(Pjll, pop1, offset); + } + +#else + case cJU_JPLEAF3: + { + Word_t lsb; + PREPL_DCD(3); + JU_COPY3_PINDEX_TO_LONG(lsb, ((uint8_t *) Pjll) + (3 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(3))) | lsb; + JU_RET_FOUND_LEAF3(Pjll, pop1, offset); + } + + case cJU_JPLEAF4: + + PREPL_DCD(4); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(4))) + | ((uint32_t *) Pjll)[offset]; + JU_RET_FOUND_LEAF4(Pjll, pop1, offset); + + case cJU_JPLEAF5: + { + Word_t lsb; + PREPL_DCD(5); + JU_COPY5_PINDEX_TO_LONG(lsb, ((uint8_t *) Pjll) + (5 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(5))) | lsb; + JU_RET_FOUND_LEAF5(Pjll, pop1, offset); + } + + case cJU_JPLEAF6: + { + Word_t lsb; + PREPL_DCD(6); + JU_COPY6_PINDEX_TO_LONG(lsb, ((uint8_t *) Pjll) + (6 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(6))) | lsb; + JU_RET_FOUND_LEAF6(Pjll, pop1, offset); + } + + case cJU_JPLEAF7: + { + Word_t lsb; + PREPL; + JU_COPY7_PINDEX_TO_LONG(lsb, ((uint8_t *) Pjll) + (7 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(7))) | lsb; + JU_RET_FOUND_LEAF7(Pjll, pop1, offset); + } +#endif + + +// ---------------------------------------------------------------------------- +// BITMAP LEAF: +// +// Return the Index at the proper ordinal (see SETOFFSET()) in the leaf by +// counting bits. First copy Dcd bytes (always present since state 1 < +// cJU_ROOTSTATE) to *PIndex. +// +// Note: The preceding branch traversal code MIGHT set pop1 for this expanse +// (bitmap leaf) as a side-effect, but dont depend on that. + + case cJU_JPLEAF_B1: + { + Pjlb_t Pjlb; + + JU_SETDCD(*PIndex, Pjp, 1); + Pjlb = P_JLB(Pjp->jp_Addr); + pop1 = JU_JPLEAF_POP0(Pjp) + 1; + +// COUNT UPWARD, adding the pop1 of each subexpanse: +// +// The entire bitmap should fit in one cache line, but still try to save some +// CPU time by counting the fewest possible number of subexpanses from the +// bitmap. +// +// See header comments about limitations of this for Judy*ByCount(). + +#ifndef NOSMARTJLB // enable to turn off smart code for comparison purposes. + + if (LOWERHALF(Count0, pop1lower, pop1)) + { +#endif +#ifdef SMARTMETRICS + ++jlb_upward; +#endif + for (subexp = 0; subexp < cJU_NUMSUBEXPL; ++subexp) + { + pop1 = j__udyCountBitsL(JU_JLB_BITMAP(Pjlb, subexp)); + +// Warning: pop1lower and pop1 are unsigned, see earlier comment: + + if (pop1lower + pop1 > Count0) + goto LeafB1; // Index is in this subexpanse. + + pop1lower += pop1; // add this subexpanses pop1. + } +#ifndef NOSMARTJLB // enable to turn off smart code for comparison purposes. + } + + +// COUNT DOWNWARD, subtracting each "above" subexpanses pop1 from the whole +// expanses pop1: + + else + { +#ifdef SMARTMETRICS + ++jlb_downward; +#endif + pop1lower += pop1; // add whole leaf to start. + + for (subexp = cJU_NUMSUBEXPL - 1; subexp >= 0; --subexp) + { + pop1lower -= j__udyCountBitsL(JU_JLB_BITMAP(Pjlb, subexp)); + +// Beware unsigned math problems: + + if ((pop1lower == 0) || (pop1lower - 1 < Count0)) + goto LeafB1; // Index is in this subexpanse. + } + } +#endif // NOSMARTJLB + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // should never get here. + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + +// RETURN INDEX FOUND: +// +// Come here with subexp set to the correct subexpanse, and pop1lower set to +// the sum for all lower expanses and subexpanses in the Judy tree. Calculate +// and save in *PIndex the digit corresponding to the ordinal in this +// subexpanse. + +LeafB1: + SETOFFSET(offset, Count0, pop1lower, Pjp); + JU_BITMAPDIGITL(digit, subexp, JU_JLB_BITMAP(Pjlb, subexp), offset); + JU_SETDIGIT1(*PIndex, digit); + JU_RET_FOUND_LEAF_B1(Pjlb, subexp, offset); +// == return((PPvoid_t) (P_JV(JL_JLB_PVALUE(Pjlb, subexp)) + offset)) + + } // case cJU_JPLEAF_B1 + + +#ifdef JUDY1 +// ---------------------------------------------------------------------------- +// FULL POPULATION: +// +// Copy Dcd bytes (always present since state 1 < cJU_ROOTSTATE) to *PIndex, +// then set the appropriate digit for the ordinal (see SETOFFSET()) in the leaf +// as the LSB in *PIndex. + + case cJ1_JPFULLPOPU1: + + JU_SETDCD(*PIndex, Pjp, 1); + SETOFFSET(offset, Count0, pop1lower, Pjp); + assert(offset >= 0); + assert(offset <= cJU_JPFULLPOPU1_POP0); + JU_SETDIGIT1(*PIndex, offset); + JU_RET_FOUND_FULLPOPU1; +#endif + + +// ---------------------------------------------------------------------------- +// IMMEDIATE: +// +// Locate the Index with the proper ordinal (see SETOFFSET()) in the Immediate, +// depending on leaf Index Size and pop1. Note: There are no Dcd bytes in an +// Immediate JP, but in a cJU_JPIMMED_*_01 JP, the field holds the least bytes +// of the immediate Index. + +#define SET_01(cState) JU_SETDIGITS(*PIndex, JU_JPDCDPOP0(Pjp), cState) + + case cJU_JPIMMED_1_01: SET_01(1); goto Imm_01; + case cJU_JPIMMED_2_01: SET_01(2); goto Imm_01; + case cJU_JPIMMED_3_01: SET_01(3); goto Imm_01; +#ifdef JU_64BIT + case cJU_JPIMMED_4_01: SET_01(4); goto Imm_01; + case cJU_JPIMMED_5_01: SET_01(5); goto Imm_01; + case cJU_JPIMMED_6_01: SET_01(6); goto Imm_01; + case cJU_JPIMMED_7_01: SET_01(7); goto Imm_01; +#endif + +Imm_01: + + DBGCODE(SETOFFSET_IMM_CK(offset, Count0, pop1lower, 1);) + JU_RET_FOUND_IMM_01(Pjp); + +// Shorthand for where to find start of Index bytes array: + +#ifdef JUDY1 +#define PJI (Pjp->jp_1Index) +#else +#define PJI (Pjp->jp_LIndex) +#endif + +// Optional code to check the remaining ordinal (see SETOFFSET_IMM()) against +// the Index Size of the Immediate: + +#ifndef DEBUG // simple placeholder: +#define IMM(cPop1,Next) \ + goto Next +#else // extra pop1-specific checking: +#define IMM(cPop1,Next) \ + SETOFFSET_IMM_CK(offset, Count0, pop1lower, cPop1); \ + goto Next +#endif + + case cJU_JPIMMED_1_02: IMM( 2, Imm1); + case cJU_JPIMMED_1_03: IMM( 3, Imm1); +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_1_04: IMM( 4, Imm1); + case cJU_JPIMMED_1_05: IMM( 5, Imm1); + case cJU_JPIMMED_1_06: IMM( 6, Imm1); + case cJU_JPIMMED_1_07: IMM( 7, Imm1); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_1_08: IMM( 8, Imm1); + case cJ1_JPIMMED_1_09: IMM( 9, Imm1); + case cJ1_JPIMMED_1_10: IMM(10, Imm1); + case cJ1_JPIMMED_1_11: IMM(11, Imm1); + case cJ1_JPIMMED_1_12: IMM(12, Imm1); + case cJ1_JPIMMED_1_13: IMM(13, Imm1); + case cJ1_JPIMMED_1_14: IMM(14, Imm1); + case cJ1_JPIMMED_1_15: IMM(15, Imm1); +#endif + +Imm1: SETOFFSET_IMM(offset, Count0, pop1lower); + JU_SETDIGIT1(*PIndex, ((uint8_t *) PJI)[offset]); + JU_RET_FOUND_IMM(Pjp, offset); + +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_2_02: IMM(2, Imm2); + case cJU_JPIMMED_2_03: IMM(3, Imm2); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_2_04: IMM(4, Imm2); + case cJ1_JPIMMED_2_05: IMM(5, Imm2); + case cJ1_JPIMMED_2_06: IMM(6, Imm2); + case cJ1_JPIMMED_2_07: IMM(7, Imm2); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) +Imm2: SETOFFSET_IMM(offset, Count0, pop1lower); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(2))) + | ((uint16_t *) PJI)[offset]; + JU_RET_FOUND_IMM(Pjp, offset); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_3_02: IMM(2, Imm3); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_3_03: IMM(3, Imm3); + case cJ1_JPIMMED_3_04: IMM(4, Imm3); + case cJ1_JPIMMED_3_05: IMM(5, Imm3); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) +Imm3: + { + Word_t lsb; + SETOFFSET_IMM(offset, Count0, pop1lower); + JU_COPY3_PINDEX_TO_LONG(lsb, ((uint8_t *) PJI) + (3 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(3))) | lsb; + JU_RET_FOUND_IMM(Pjp, offset); + } +#endif + +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_4_02: IMM(2, Imm4); + case cJ1_JPIMMED_4_03: IMM(3, Imm4); + +Imm4: SETOFFSET_IMM(offset, Count0, pop1lower); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(4))) + | ((uint32_t *) PJI)[offset]; + JU_RET_FOUND_IMM(Pjp, offset); + + case cJ1_JPIMMED_5_02: IMM(2, Imm5); + case cJ1_JPIMMED_5_03: IMM(3, Imm5); + +Imm5: + { + Word_t lsb; + SETOFFSET_IMM(offset, Count0, pop1lower); + JU_COPY5_PINDEX_TO_LONG(lsb, ((uint8_t *) PJI) + (5 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(5))) | lsb; + JU_RET_FOUND_IMM(Pjp, offset); + } + + case cJ1_JPIMMED_6_02: IMM(2, Imm6); + +Imm6: + { + Word_t lsb; + SETOFFSET_IMM(offset, Count0, pop1lower); + JU_COPY6_PINDEX_TO_LONG(lsb, ((uint8_t *) PJI) + (6 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(6))) | lsb; + JU_RET_FOUND_IMM(Pjp, offset); + } + + case cJ1_JPIMMED_7_02: IMM(2, Imm7); + +Imm7: + { + Word_t lsb; + SETOFFSET_IMM(offset, Count0, pop1lower); + JU_COPY7_PINDEX_TO_LONG(lsb, ((uint8_t *) PJI) + (7 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(7))) | lsb; + JU_RET_FOUND_IMM(Pjp, offset); + } +#endif // (JUDY1 && JU_64BIT) + + +// ---------------------------------------------------------------------------- +// UNEXPECTED JP TYPES: + + default: JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // SMByCount switch. + + /*NOTREACHED*/ + +} // Judy1ByCount() / JudyLByCount() |