From 7877a98bd9c00db5e81dd2f8c734cba2bab20be7 Mon Sep 17 00:00:00 2001 From: Daniel Baumann Date: Fri, 12 Aug 2022 09:26:17 +0200 Subject: Merging upstream version 1.36.0. Signed-off-by: Daniel Baumann --- libnetdata/libjudy/src/JudyL/JudyLPrev.c | 1890 ++++++++++++++++++++++++++++++ 1 file changed, 1890 insertions(+) create mode 100644 libnetdata/libjudy/src/JudyL/JudyLPrev.c (limited to 'libnetdata/libjudy/src/JudyL/JudyLPrev.c') diff --git a/libnetdata/libjudy/src/JudyL/JudyLPrev.c b/libnetdata/libjudy/src/JudyL/JudyLPrev.c new file mode 100644 index 000000000..4bcdccf10 --- /dev/null +++ b/libnetdata/libjudy/src/JudyL/JudyLPrev.c @@ -0,0 +1,1890 @@ +// 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: 4.54 $ $Source: /judy/src/JudyCommon/JudyPrevNext.c $ +// +// Judy*Prev() and Judy*Next() functions for Judy1 and JudyL. +// Compile with one of -DJUDY1 or -DJUDYL. +// +// Compile with -DJUDYNEXT for the Judy*Next() function; otherwise defaults to +// Judy*Prev(). + +#if (! (defined(JUDY1) || defined(JUDYL))) +#error: One of -DJUDY1 or -DJUDYL must be specified. +#endif + +#ifndef JUDYNEXT +#ifndef JUDYPREV +#define JUDYPREV 1 // neither set => use default. +#endif +#endif + +#ifdef JUDY1 +#include "Judy1.h" +#else +#include "JudyL.h" +#endif + +#include "JudyPrivate1L.h" + + +// **************************************************************************** +// J U D Y 1 P R E V +// J U D Y 1 N E X T +// J U D Y L P R E V +// J U D Y L N E X T +// +// See the manual entry for the API. +// +// OVERVIEW OF Judy*Prev(): +// +// Use a reentrant switch statement (state machine, SM1 = "get") to decode the +// callers *PIndex-1, starting with the (PArray), through branches, if +// any, down to an immediate or a leaf. Look for *PIndex-1 in that leaf, and +// if found, return it. +// +// A dead end is either a branch that does not contain a JP for the appropriate +// digit in *PIndex-1, or a leaf that does not contain the undecoded digits of +// *PIndex-1. Upon reaching a dead end, backtrack through the leaf/branches +// that were just traversed, using a list (history) of parent JPs that is built +// while going forward in SM1Get. Start with the current leaf or branch. In a +// backtracked leaf, look for an Index less than *PIndex-1. In each +// backtracked branch, look "sideways" for the next JP, if any, lower than the +// one for the digit (from *PIndex-1) that was previously decoded. While +// backtracking, if a leaf has no previous Index or a branch has no lower JP, +// go to its parent branch in turn. Upon reaching the JRP, return failure, "no +// previous Index". The backtrack process is sufficiently different from +// SM1Get to merit its own separate reentrant switch statement (SM2 = +// "backtrack"). +// +// While backtracking, upon finding a lower JP in a branch, there is certain to +// be a "prev" Index under that JP (unless the Judy array is corrupt). +// Traverse forward again, this time taking the last (highest, right-most) JP +// in each branch, and the last (highest) Index upon reaching an immediate or a +// leaf. This traversal is sufficiently different from SM1Get and SM2Backtrack +// to merit its own separate reentrant switch statement (SM3 = "findlimit"). +// +// "Decode" bytes in JPs complicate this process a little. In SM1Get, when a +// JP is a narrow pointer, that is, when states are skipped (so the skipped +// digits are stored in jp_DcdPopO), compare the relevant digits to the same +// digits in *PIndex-1. If they are EQUAL, proceed in SM1Get as before. If +// jp_DcdPopOs digits are GREATER, treat the JP as a dead end and proceed in +// SM2Backtrack. If jp_DcdPopOs digits are LESS, treat the JP as if it had +// just been found during a backtrack and proceed directly in SM3Findlimit. +// +// Note that Decode bytes can be ignored in SM3Findlimit; they dont matter. +// Also note that in practice the Decode bytes are routinely compared with +// *PIndex-1 because thats simpler and no slower than first testing for +// narrowness. +// +// Decode bytes also make it unnecessary to construct the Index to return (the +// revised *PIndex) during the search. This step is deferred until finding an +// Index during backtrack or findlimit, before returning it. The first digit +// of *PIndex is derived (saved) based on which JP is used in a JRP branch. +// The remaining digits are obtained from the jp_DcdPopO field in the JP (if +// any) above the immediate or leaf containing the found (prev) Index, plus the +// remaining digit(s) in the immediate or leaf itself. In the case of a LEAFW, +// the Index to return is found directly in the leaf. +// +// Note: Theoretically, as described above, upon reaching a dead end, SM1Get +// passes control to SM2Backtrack to look sideways, even in a leaf. Actually +// its a little more efficient for the SM1Get leaf cases to shortcut this and +// take care of the sideways searches themselves. Hence the history list only +// contains branch JPs, and SM2Backtrack only handles branches. In fact, even +// the branch handling cases in SM1Get do some shortcutting (sideways +// searching) to avoid pushing history and calling SM2Backtrack unnecessarily. +// +// Upon reaching an Index to return after backtracking, *PIndex must be +// modified to the found Index. In principle this could be done by building +// the Index from a saved rootdigit (in the top branch) plus the Dcd bytes from +// the parent JP plus the appropriate Index bytes from the leaf. However, +// Immediates are difficult because their parent JPs lack one (last) digit. So +// instead just build the *PIndex to return "top down" while backtracking and +// findlimiting. +// +// This function is written iteratively for speed, rather than recursively. +// +// CAVEATS: +// +// Why use a backtrack list (history stack), since it has finite size? The +// size is small for Judy on both 32-bit and 64-bit systems, and a list (really +// just an array) is fast to maintain and use. Other alternatives include +// doing a lookahead (lookaside) in each branch while traversing forward +// (decoding), and restarting from the top upon a dead end. +// +// A lookahead means noting the last branch traversed which contained a +// non-null JP lower than the one specified by a digit in *PIndex-1, and +// returning to that point for SM3Findlimit. This seems like a good idea, and +// should be pretty cheap for linear and bitmap branches, but it could result +// in up to 31 unnecessary additional cache line fills (in extreme cases) for +// every uncompressed branch traversed. We have considered means of attaching +// to or hiding within an uncompressed branch (in null JPs) a "cache line map" +// or other structure, such as an offset to the next non-null JP, that would +// speed this up, but it seems unnecessary merely to avoid having a +// finite-length list (array). (If JudySL is ever made "native", the finite +// list length will be an issue.) +// +// Restarting at the top of the Judy array after a dead end requires a careful +// modification of *PIndex-1 to decrement the digit for the parent branch and +// set the remaining lower digits to all 1s. This must be repeated each time a +// parent branch contains another dead end, so even though it should all happen +// in cache, the CPU time can be excessive. (For JudySL or an equivalent +// "infinitely deep" Judy array, consider a hybrid of a large, finite, +// "circular" list and a restart-at-top when the list is backtracked to +// exhaustion.) +// +// Why search for *PIndex-1 instead of *PIndex during SM1Get? In rare +// instances this prevents an unnecessary decode down the wrong path followed +// by a backtrack; its pretty cheap to set up initially; and it means the +// SM1Get machine can simply return if/when it finds that Index. +// +// TBD: Wed like to enhance this function to make successive searches faster. +// This would require saving some previous state, including the previous Index +// returned, and in which leaf it was found. If the next call is for the same +// Index and the array has not been modified, start at the same leaf. This +// should be much easier to implement since this is iterative rather than +// recursive code. +// +// VARIATIONS FOR Judy*Next(): +// +// The Judy*Next() code is nearly a perfect mirror of the Judy*Prev() code. +// See the Judy*Prev() overview comments, and mentally switch the following: +// +// - "*PIndex-1" => "*PIndex+1" +// - "less than" => "greater than" +// - "lower" => "higher" +// - "lowest" => "highest" +// - "next-left" => "next-right" +// - "right-most" => "left-most" +// +// Note: SM3Findlimit could be called SM3Findmax/SM3Findmin, but a common name +// for both Prev and Next means many fewer ifdefs in this code. +// +// TBD: Currently this code traverses a JP whether its expanse is partially or +// completely full (populated). For Judy1 (only), since there is no value area +// needed, consider shortcutting to a "success" return upon encountering a full +// JP in SM1Get (or even SM3Findlimit?) A full JP looks like this: +// +// (((JU_JPDCDPOP0(Pjp) ^ cJU_ALLONES) & cJU_POP0MASK(cLevel)) == 0) + +#ifdef JUDY1 +#ifdef JUDYPREV +FUNCTION int Judy1Prev +#else +FUNCTION int Judy1Next +#endif +#else +#ifdef JUDYPREV +FUNCTION PPvoid_t JudyLPrev +#else +FUNCTION PPvoid_t JudyLNext +#endif +#endif + ( + Pcvoid_t PArray, // Judy array to search. + Word_t * PIndex, // starting point and result. + PJError_t PJError // optional, for returning error info. + ) +{ + Pjp_t Pjp, Pjp2; // current JPs. + Pjbl_t Pjbl; // Pjp->jp_Addr masked and cast to types: + Pjbb_t Pjbb; + Pjbu_t Pjbu; + +// Note: The following initialization is not strictly required but it makes +// gcc -Wall happy because there is an "impossible" path from Immed handling to +// SM1LeafLImm code that looks like Pjll might be used before set: + + Pjll_t Pjll = (Pjll_t) NULL; + Word_t state; // current state in SM. + Word_t digit; // next digit to decode from Index. + +// Note: The following initialization is not strictly required but it makes +// gcc -Wall happy because there is an "impossible" path from Immed handling to +// SM1LeafLImm code (for JudyL & JudyPrev only) that looks like pop1 might be +// used before set: + +#if (defined(JUDYL) && defined(JUDYPREV)) + Word_t pop1 = 0; // in a leaf. +#else + Word_t pop1; // in a leaf. +#endif + int offset; // linear branch/leaf, from j__udySearchLeaf*(). + int subexp; // subexpanse in a bitmap branch. + Word_t bitposmask; // bit in bitmap for Index. + +// History for SM2Backtrack: +// +// For a given histnum, APjphist[histnum] is a parent JP that points to a +// branch, and Aoffhist[histnum] is the offset of the NEXT JP in the branch to +// which the parent JP points. The meaning of Aoffhist[histnum] depends on the +// type of branch to which the parent JP points: +// +// Linear: Offset of the next JP in the JP list. +// +// Bitmap: Which subexpanse, plus the offset of the next JP in the +// subexpanses JP list (to avoid bit-counting again), plus for Judy*Next(), +// hidden one byte to the left, which digit, because Judy*Next() also needs +// this. +// +// Uncompressed: Digit, which is actually the offset of the JP in the branch. +// +// Note: Only branch JPs are stored in APjphist[] because, as explained +// earlier, SM1Get shortcuts sideways searches in leaves (and even in branches +// in some cases), so SM2Backtrack only handles branches. + +#define HISTNUMMAX cJU_ROOTSTATE // maximum branches traversable. + Pjp_t APjphist[HISTNUMMAX]; // list of branch JPs traversed. + int Aoffhist[HISTNUMMAX]; // list of next JP offsets; see above. + int histnum = 0; // number of JPs now in list. + + +// ---------------------------------------------------------------------------- +// M A C R O S +// +// These are intended to make the code a bit more readable and less redundant. + + +// "PUSH" AND "POP" Pjp AND offset ON HISTORY STACKS: +// +// Note: Ensure a corrupt Judy array does not overflow *hist[]. Meanwhile, +// underflowing *hist[] simply means theres no more room to backtrack => +// "no previous/next Index". + +#define HISTPUSH(Pjp,Offset) \ + APjphist[histnum] = (Pjp); \ + Aoffhist[histnum] = (Offset); \ + \ + if (++histnum >= HISTNUMMAX) \ + { \ + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT) \ + JUDY1CODE(return(JERRI );) \ + JUDYLCODE(return(PPJERR);) \ + } + +#define HISTPOP(Pjp,Offset) \ + if ((histnum--) < 1) JU_RET_NOTFOUND; \ + (Pjp) = APjphist[histnum]; \ + (Offset) = Aoffhist[histnum] + +// How to pack/unpack Aoffhist[] values for bitmap branches: + +#ifdef JUDYPREV + +#define HISTPUSHBOFF(Subexp,Offset,Digit) \ + (((Subexp) * cJU_BITSPERSUBEXPB) | (Offset)) + +#define HISTPOPBOFF(Subexp,Offset,Digit) \ + (Subexp) = (Offset) / cJU_BITSPERSUBEXPB; \ + (Offset) %= cJU_BITSPERSUBEXPB +#else + +#define HISTPUSHBOFF(Subexp,Offset,Digit) \ + (((Digit) << cJU_BITSPERBYTE) \ + | ((Subexp) * cJU_BITSPERSUBEXPB) | (Offset)) + +#define HISTPOPBOFF(Subexp,Offset,Digit) \ + (Digit) = (Offset) >> cJU_BITSPERBYTE; \ + (Subexp) = ((Offset) & JU_LEASTBYTESMASK(1)) / cJU_BITSPERSUBEXPB; \ + (Offset) %= cJU_BITSPERSUBEXPB +#endif + + +// CHECK FOR NULL JP: + +#define JPNULL(Type) (((Type) >= cJU_JPNULL1) && ((Type) <= cJU_JPNULLMAX)) + + +// SEARCH A BITMAP: +// +// This is a weak analog of j__udySearchLeaf*() for bitmaps. Return the actual +// or next-left position, base 0, of Digit in the single uint32_t bitmap, also +// given a Bitposmask for Digit. +// +// Unlike j__udySearchLeaf*(), the offset is not returned bit-complemented if +// Digits bit is unset, because the caller can check the bitmap themselves to +// determine that. Also, if Digits bit is unset, the returned offset is to +// the next-left JP (including -1), not to the "ideal" position for the Index = +// next-right JP. +// +// Shortcut and skip calling j__udyCountBits*() if the bitmap is full, in which +// case (Digit % cJU_BITSPERSUBEXP*) itself is the base-0 offset. +// +// TBD for Judy*Next(): Should this return next-right instead of next-left? +// That is, +1 from current value? Maybe not, if Digits bit IS set, +1 would +// be wrong. + +#define SEARCHBITMAPB(Bitmap,Digit,Bitposmask) \ + (((Bitmap) == cJU_FULLBITMAPB) ? (Digit % cJU_BITSPERSUBEXPB) : \ + j__udyCountBitsB((Bitmap) & JU_MASKLOWERINC(Bitposmask)) - 1) + +#define SEARCHBITMAPL(Bitmap,Digit,Bitposmask) \ + (((Bitmap) == cJU_FULLBITMAPL) ? (Digit % cJU_BITSPERSUBEXPL) : \ + j__udyCountBitsL((Bitmap) & JU_MASKLOWERINC(Bitposmask)) - 1) + +#ifdef JUDYPREV +// Equivalent to search for the highest offset in Bitmap: + +#define SEARCHBITMAPMAXB(Bitmap) \ + (((Bitmap) == cJU_FULLBITMAPB) ? cJU_BITSPERSUBEXPB - 1 : \ + j__udyCountBitsB(Bitmap) - 1) + +#define SEARCHBITMAPMAXL(Bitmap) \ + (((Bitmap) == cJU_FULLBITMAPL) ? cJU_BITSPERSUBEXPL - 1 : \ + j__udyCountBitsL(Bitmap) - 1) +#endif + + +// CHECK DECODE BYTES: +// +// Check Decode bytes in a JP against the equivalent portion of *PIndex. If +// *PIndex is lower (for Judy*Prev()) or higher (for Judy*Next()), this JP is a +// dead end (the same as if it had been absent in a linear or bitmap branch or +// null in an uncompressed branch), enter SM2Backtrack; otherwise enter +// SM3Findlimit to find the highest/lowest Index under this JP, as if the code +// had already backtracked to this JP. + +#ifdef JUDYPREV +#define CDcmp__ < +#else +#define CDcmp__ > +#endif + +#define CHECKDCD(cState) \ + if (JU_DCDNOTMATCHINDEX(*PIndex, Pjp, cState)) \ + { \ + if ((*PIndex & cJU_DCDMASK(cState)) \ + CDcmp__(JU_JPDCDPOP0(Pjp) & cJU_DCDMASK(cState))) \ + { \ + goto SM2Backtrack; \ + } \ + goto SM3Findlimit; \ + } + + +// PREPARE TO HANDLE A LEAFW OR JRP BRANCH IN SM1: +// +// Extract a state-dependent digit from Index in a "constant" way, then jump to +// common code for multiple cases. + +#define SM1PREPB(cState,Next) \ + state = (cState); \ + digit = JU_DIGITATSTATE(*PIndex, cState); \ + goto Next + + +// PREPARE TO HANDLE A LEAFW OR JRP BRANCH IN SM3: +// +// Optionally save Dcd bytes into *PIndex, then save state and jump to common +// code for multiple cases. + +#define SM3PREPB_DCD(cState,Next) \ + JU_SETDCD(*PIndex, Pjp, cState); \ + SM3PREPB(cState,Next) + +#define SM3PREPB(cState,Next) state = (cState); goto Next + + +// ---------------------------------------------------------------------------- +// CHECK FOR SHORTCUTS: +// +// Error out if PIndex is null. Execute JU_RET_NOTFOUND if the Judy array is +// empty or *PIndex is already the minimum/maximum Index possible. +// +// Note: As documented, in case of failure *PIndex may be modified. + + if (PIndex == (PWord_t) NULL) + { + JU_SET_ERRNO(PJError, JU_ERRNO_NULLPINDEX); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + +#ifdef JUDYPREV + if ((PArray == (Pvoid_t) NULL) || ((*PIndex)-- == 0)) +#else + if ((PArray == (Pvoid_t) NULL) || ((*PIndex)++ == cJU_ALLONES)) +#endif + JU_RET_NOTFOUND; + + +// HANDLE JRP: +// +// Before even entering SM1Get, check the JRP type. For JRP branches, traverse +// the JPM; handle LEAFW leaves directly; but look for the most common cases +// first. + +// ROOT-STATE LEAF that starts with a Pop0 word; just look within the leaf: +// +// If *PIndex is in the leaf, return it; otherwise return the Index, if any, +// below where it would belong. + + if (JU_LEAFW_POP0(PArray) < cJU_LEAFW_MAXPOP1) // must be a LEAFW + { + Pjlw_t Pjlw = P_JLW(PArray); // first word of leaf. + pop1 = Pjlw[0] + 1; + + if ((offset = j__udySearchLeafW(Pjlw + 1, pop1, *PIndex)) + >= 0) // Index is present. + { + assert(offset < pop1); // in expected range. + JU_RET_FOUND_LEAFW(Pjlw, pop1, offset); // *PIndex is set. + } + +#ifdef JUDYPREV + if ((offset = ~offset) == 0) // no next-left Index. +#else + if ((offset = ~offset) >= pop1) // no next-right Index. +#endif + JU_RET_NOTFOUND; + + assert(offset <= pop1); // valid result. + +#ifdef JUDYPREV + *PIndex = Pjlw[offset--]; // next-left Index, base 1. +#else + *PIndex = Pjlw[offset + 1]; // next-right Index, base 1. +#endif + JU_RET_FOUND_LEAFW(Pjlw, pop1, offset); // base 0. + + } + else // JRP BRANCH + { + Pjpm_t Pjpm = P_JPM(PArray); + Pjp = &(Pjpm->jpm_JP); + +// goto SM1Get; + } + +// ============================================================================ +// STATE MACHINE 1 -- GET INDEX: +// +// Search for *PIndex (already decremented/incremented so as to be inclusive). +// If found, return it. Otherwise in theory hand off to SM2Backtrack or +// SM3Findlimit, but in practice "shortcut" by first sideways searching the +// current branch or leaf upon hitting a dead end. During sideways search, +// modify *PIndex to a new path taken. +// +// ENTRY: Pjp points to next JP to interpret, whose Decode bytes have not yet +// been checked. This JP is not yet listed in history. +// +// Note: Check Decode bytes at the start of each loop, not after looking up a +// new JP, so its easy to do constant shifts/masks, although this requires +// cautious handling of Pjp, offset, and *hist[] for correct entry to +// SM2Backtrack. +// +// EXIT: Return, or branch to SM2Backtrack or SM3Findlimit with correct +// interface, as described elsewhere. +// +// WARNING: For run-time efficiency the following cases replicate code with +// varying constants, rather than using common code with variable values! + +SM1Get: // return here for next branch/leaf. + + switch (JU_JPTYPE(Pjp)) + { + + +// ---------------------------------------------------------------------------- +// LINEAR BRANCH: +// +// Check Decode bytes, if any, in the current JP, then search for a JP for the +// next digit in *PIndex. + + case cJU_JPBRANCH_L2: CHECKDCD(2); SM1PREPB(2, SM1BranchL); + case cJU_JPBRANCH_L3: CHECKDCD(3); SM1PREPB(3, SM1BranchL); +#ifdef JU_64BIT + case cJU_JPBRANCH_L4: CHECKDCD(4); SM1PREPB(4, SM1BranchL); + case cJU_JPBRANCH_L5: CHECKDCD(5); SM1PREPB(5, SM1BranchL); + case cJU_JPBRANCH_L6: CHECKDCD(6); SM1PREPB(6, SM1BranchL); + case cJU_JPBRANCH_L7: CHECKDCD(7); SM1PREPB(7, SM1BranchL); +#endif + case cJU_JPBRANCH_L: SM1PREPB(cJU_ROOTSTATE, SM1BranchL); + +// Common code (state-independent) for all cases of linear branches: + +SM1BranchL: + Pjbl = P_JBL(Pjp->jp_Addr); + +// Found JP matching current digit in *PIndex; record parent JP and the next +// JPs offset, and iterate to the next JP: + + if ((offset = j__udySearchLeaf1((Pjll_t) (Pjbl->jbl_Expanse), + Pjbl->jbl_NumJPs, digit)) >= 0) + { + HISTPUSH(Pjp, offset); + Pjp = (Pjbl->jbl_jp) + offset; + goto SM1Get; + } + +// Dead end, no JP in BranchL for next digit in *PIndex: +// +// Get the ideal location of digits JP, and if theres no next-left/right JP +// in the BranchL, shortcut and start backtracking one level up; ignore the +// current Pjp because it points to a BranchL with no next-left/right JP. + +#ifdef JUDYPREV + if ((offset = (~offset) - 1) < 0) // no next-left JP in BranchL. +#else + if ((offset = (~offset)) >= Pjbl->jbl_NumJPs) // no next-right. +#endif + goto SM2Backtrack; + +// Theres a next-left/right JP in the current BranchL; save its digit in +// *PIndex and shortcut to SM3Findlimit: + + JU_SETDIGIT(*PIndex, Pjbl->jbl_Expanse[offset], state); + Pjp = (Pjbl->jbl_jp) + offset; + goto SM3Findlimit; + + +// ---------------------------------------------------------------------------- +// BITMAP BRANCH: +// +// Check Decode bytes, if any, in the current JP, then look for a JP for the +// next digit in *PIndex. + + case cJU_JPBRANCH_B2: CHECKDCD(2); SM1PREPB(2, SM1BranchB); + case cJU_JPBRANCH_B3: CHECKDCD(3); SM1PREPB(3, SM1BranchB); +#ifdef JU_64BIT + case cJU_JPBRANCH_B4: CHECKDCD(4); SM1PREPB(4, SM1BranchB); + case cJU_JPBRANCH_B5: CHECKDCD(5); SM1PREPB(5, SM1BranchB); + case cJU_JPBRANCH_B6: CHECKDCD(6); SM1PREPB(6, SM1BranchB); + case cJU_JPBRANCH_B7: CHECKDCD(7); SM1PREPB(7, SM1BranchB); +#endif + case cJU_JPBRANCH_B: SM1PREPB(cJU_ROOTSTATE, SM1BranchB); + +// Common code (state-independent) for all cases of bitmap branches: + +SM1BranchB: + Pjbb = P_JBB(Pjp->jp_Addr); + +// Locate the digits JP in the subexpanse list, if present, otherwise the +// offset of the next-left JP, if any: + + subexp = digit / cJU_BITSPERSUBEXPB; + assert(subexp < cJU_NUMSUBEXPB); // falls in expected range. + bitposmask = JU_BITPOSMASKB(digit); + offset = SEARCHBITMAPB(JU_JBB_BITMAP(Pjbb, subexp), digit, + bitposmask); + // right range: + assert((offset >= -1) && (offset < (int) cJU_BITSPERSUBEXPB)); + +// Found JP matching current digit in *PIndex: +// +// Record the parent JP and the next JPs offset; and iterate to the next JP. + +// if (JU_BITMAPTESTB(Pjbb, digit)) // slower. + if (JU_JBB_BITMAP(Pjbb, subexp) & bitposmask) // faster. + { + // not negative since at least one bit is set: + assert(offset >= 0); + + HISTPUSH(Pjp, HISTPUSHBOFF(subexp, offset, digit)); + + if ((Pjp = P_JP(JU_JBB_PJP(Pjbb, subexp))) == (Pjp_t) NULL) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + + Pjp += offset; + goto SM1Get; // iterate to next JP. + } + +// Dead end, no JP in BranchB for next digit in *PIndex: +// +// If theres a next-left/right JP in the current BranchB, shortcut to +// SM3Findlimit. Note: offset is already set to the correct value for the +// next-left/right JP. + +#ifdef JUDYPREV + if (offset >= 0) // next-left JP is in this subexpanse. + goto SM1BranchBFindlimit; + + while (--subexp >= 0) // search next-left subexpanses. +#else + if (JU_JBB_BITMAP(Pjbb, subexp) & JU_MASKHIGHEREXC(bitposmask)) + { + ++offset; // next-left => next-right. + goto SM1BranchBFindlimit; + } + + while (++subexp < cJU_NUMSUBEXPB) // search next-right subexps. +#endif + { + if (! JU_JBB_PJP(Pjbb, subexp)) continue; // empty subexpanse. + +#ifdef JUDYPREV + offset = SEARCHBITMAPMAXB(JU_JBB_BITMAP(Pjbb, subexp)); + // expected range: + assert((offset >= 0) && (offset < cJU_BITSPERSUBEXPB)); +#else + offset = 0; +#endif + +// Save the next-left/right JPs digit in *PIndex: + +SM1BranchBFindlimit: + JU_BITMAPDIGITB(digit, subexp, JU_JBB_BITMAP(Pjbb, subexp), + offset); + JU_SETDIGIT(*PIndex, digit, state); + + if ((Pjp = P_JP(JU_JBB_PJP(Pjbb, subexp))) == (Pjp_t) NULL) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + + Pjp += offset; + goto SM3Findlimit; + } + +// Theres no next-left/right JP in the BranchB: +// +// Shortcut and start backtracking one level up; ignore the current Pjp because +// it points to a BranchB with no next-left/right JP. + + goto SM2Backtrack; + + +// ---------------------------------------------------------------------------- +// UNCOMPRESSED BRANCH: +// +// Check Decode bytes, if any, in the current JP, then look for a JP for the +// next digit in *PIndex. + + case cJU_JPBRANCH_U2: CHECKDCD(2); SM1PREPB(2, SM1BranchU); + case cJU_JPBRANCH_U3: CHECKDCD(3); SM1PREPB(3, SM1BranchU); +#ifdef JU_64BIT + case cJU_JPBRANCH_U4: CHECKDCD(4); SM1PREPB(4, SM1BranchU); + case cJU_JPBRANCH_U5: CHECKDCD(5); SM1PREPB(5, SM1BranchU); + case cJU_JPBRANCH_U6: CHECKDCD(6); SM1PREPB(6, SM1BranchU); + case cJU_JPBRANCH_U7: CHECKDCD(7); SM1PREPB(7, SM1BranchU); +#endif + case cJU_JPBRANCH_U: SM1PREPB(cJU_ROOTSTATE, SM1BranchU); + +// Common code (state-independent) for all cases of uncompressed branches: + +SM1BranchU: + Pjbu = P_JBU(Pjp->jp_Addr); + Pjp2 = (Pjbu->jbu_jp) + digit; + +// Found JP matching current digit in *PIndex: +// +// Record the parent JP and the next JPs digit, and iterate to the next JP. +// +// TBD: Instead of this, just goto SM1Get, and add cJU_JPNULL* cases to the +// SM1Get state machine? Then backtrack? However, it means you cant detect +// an inappropriate cJU_JPNULL*, when it occurs in other than a BranchU, and +// return JU_RET_CORRUPT. + + if (! JPNULL(JU_JPTYPE(Pjp2))) // digit has a JP. + { + HISTPUSH(Pjp, digit); + Pjp = Pjp2; + goto SM1Get; + } + +// Dead end, no JP in BranchU for next digit in *PIndex: +// +// Search for a next-left/right JP in the current BranchU, and if one is found, +// save its digit in *PIndex and shortcut to SM3Findlimit: + +#ifdef JUDYPREV + while (digit >= 1) + { + Pjp = (Pjbu->jbu_jp) + (--digit); +#else + while (digit < cJU_BRANCHUNUMJPS - 1) + { + Pjp = (Pjbu->jbu_jp) + (++digit); +#endif + if (JPNULL(JU_JPTYPE(Pjp))) continue; + + JU_SETDIGIT(*PIndex, digit, state); + goto SM3Findlimit; + } + +// Theres no next-left/right JP in the BranchU: +// +// Shortcut and start backtracking one level up; ignore the current Pjp because +// it points to a BranchU with no next-left/right JP. + + goto SM2Backtrack; + + +// ---------------------------------------------------------------------------- +// LINEAR LEAF: +// +// Check Decode bytes, if any, in the current JP, then search the leaf for +// *PIndex. + +#define SM1LEAFL(Func) \ + Pjll = P_JLL(Pjp->jp_Addr); \ + pop1 = JU_JPLEAF_POP0(Pjp) + 1; \ + offset = Func(Pjll, pop1, *PIndex); \ + goto SM1LeafLImm + +#if (defined(JUDYL) || (! defined(JU_64BIT))) + case cJU_JPLEAF1: CHECKDCD(1); SM1LEAFL(j__udySearchLeaf1); +#endif + case cJU_JPLEAF2: CHECKDCD(2); SM1LEAFL(j__udySearchLeaf2); + case cJU_JPLEAF3: CHECKDCD(3); SM1LEAFL(j__udySearchLeaf3); + +#ifdef JU_64BIT + case cJU_JPLEAF4: CHECKDCD(4); SM1LEAFL(j__udySearchLeaf4); + case cJU_JPLEAF5: CHECKDCD(5); SM1LEAFL(j__udySearchLeaf5); + case cJU_JPLEAF6: CHECKDCD(6); SM1LEAFL(j__udySearchLeaf6); + case cJU_JPLEAF7: CHECKDCD(7); SM1LEAFL(j__udySearchLeaf7); +#endif + +// Common code (state-independent) for all cases of linear leaves and +// immediates: + +SM1LeafLImm: + if (offset >= 0) // *PIndex is in LeafL / Immed. +#ifdef JUDY1 + JU_RET_FOUND; +#else + { // JudyL is trickier... + switch (JU_JPTYPE(Pjp)) + { +#if (defined(JUDYL) || (! defined(JU_64BIT))) + case cJU_JPLEAF1: JU_RET_FOUND_LEAF1(Pjll, pop1, offset); +#endif + case cJU_JPLEAF2: JU_RET_FOUND_LEAF2(Pjll, pop1, offset); + case cJU_JPLEAF3: JU_RET_FOUND_LEAF3(Pjll, pop1, offset); +#ifdef JU_64BIT + case cJU_JPLEAF4: JU_RET_FOUND_LEAF4(Pjll, pop1, offset); + case cJU_JPLEAF5: JU_RET_FOUND_LEAF5(Pjll, pop1, offset); + case cJU_JPLEAF6: JU_RET_FOUND_LEAF6(Pjll, pop1, offset); + case cJU_JPLEAF7: JU_RET_FOUND_LEAF7(Pjll, pop1, offset); +#endif + + case cJU_JPIMMED_1_01: + case cJU_JPIMMED_2_01: + case cJU_JPIMMED_3_01: +#ifdef JU_64BIT + case cJU_JPIMMED_4_01: + case cJU_JPIMMED_5_01: + case cJU_JPIMMED_6_01: + case cJU_JPIMMED_7_01: +#endif + JU_RET_FOUND_IMM_01(Pjp); + + case cJU_JPIMMED_1_02: + case cJU_JPIMMED_1_03: +#ifdef JU_64BIT + case cJU_JPIMMED_1_04: + case cJU_JPIMMED_1_05: + case cJU_JPIMMED_1_06: + case cJU_JPIMMED_1_07: + case cJU_JPIMMED_2_02: + case cJU_JPIMMED_2_03: + case cJU_JPIMMED_3_02: +#endif + JU_RET_FOUND_IMM(Pjp, offset); + } + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // impossible? + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // found *PIndex + +#endif // JUDYL + +// Dead end, no Index in LeafL / Immed for remaining digit(s) in *PIndex: +// +// Get the ideal location of Index, and if theres no next-left/right Index in +// the LeafL / Immed, shortcut and start backtracking one level up; ignore the +// current Pjp because it points to a LeafL / Immed with no next-left/right +// Index. + +#ifdef JUDYPREV + if ((offset = (~offset) - 1) < 0) // no next-left Index. +#else + if ((offset = (~offset)) >= pop1) // no next-right Index. +#endif + goto SM2Backtrack; + +// Theres a next-left/right Index in the current LeafL / Immed; shortcut by +// copying its digit(s) to *PIndex and returning it. +// +// Unfortunately this is pretty hairy, especially avoiding endian issues. +// +// The cJU_JPLEAF* cases are very similar to same-index-size cJU_JPIMMED* cases +// for *_02 and above, but must return differently, at least for JudyL, so +// spell them out separately here at the cost of a little redundant code for +// Judy1. + + switch (JU_JPTYPE(Pjp)) + { +#if (defined(JUDYL) || (! defined(JU_64BIT))) + case cJU_JPLEAF1: + + JU_SETDIGIT1(*PIndex, ((uint8_t *) Pjll)[offset]); + JU_RET_FOUND_LEAF1(Pjll, pop1, offset); +#endif + + case cJU_JPLEAF2: + + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(2))) + | ((uint16_t *) Pjll)[offset]; + JU_RET_FOUND_LEAF2(Pjll, pop1, offset); + + case cJU_JPLEAF3: + { + Word_t lsb; + JU_COPY3_PINDEX_TO_LONG(lsb, ((uint8_t *) Pjll) + (3 * offset)); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(3))) | lsb; + JU_RET_FOUND_LEAF3(Pjll, pop1, offset); + } + +#ifdef JU_64BIT + case cJU_JPLEAF4: + + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(4))) + | ((uint32_t *) Pjll)[offset]; + JU_RET_FOUND_LEAF4(Pjll, pop1, offset); + + case cJU_JPLEAF5: + { + Word_t lsb; + 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; + 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; + 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 // JU_64BIT + +#define SET_01(cState) JU_SETDIGITS(*PIndex, JU_JPDCDPOP0(Pjp), cState) + + case cJU_JPIMMED_1_01: SET_01(1); goto SM1Imm_01; + case cJU_JPIMMED_2_01: SET_01(2); goto SM1Imm_01; + case cJU_JPIMMED_3_01: SET_01(3); goto SM1Imm_01; +#ifdef JU_64BIT + case cJU_JPIMMED_4_01: SET_01(4); goto SM1Imm_01; + case cJU_JPIMMED_5_01: SET_01(5); goto SM1Imm_01; + case cJU_JPIMMED_6_01: SET_01(6); goto SM1Imm_01; + case cJU_JPIMMED_7_01: SET_01(7); goto SM1Imm_01; +#endif +SM1Imm_01: 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 + + case cJU_JPIMMED_1_02: + case cJU_JPIMMED_1_03: +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_1_04: + case cJU_JPIMMED_1_05: + case cJU_JPIMMED_1_06: + case cJU_JPIMMED_1_07: +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_1_08: + case cJ1_JPIMMED_1_09: + case cJ1_JPIMMED_1_10: + case cJ1_JPIMMED_1_11: + case cJ1_JPIMMED_1_12: + case cJ1_JPIMMED_1_13: + case cJ1_JPIMMED_1_14: + case cJ1_JPIMMED_1_15: +#endif + JU_SETDIGIT1(*PIndex, ((uint8_t *) PJI)[offset]); + JU_RET_FOUND_IMM(Pjp, offset); + +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_2_02: + case cJU_JPIMMED_2_03: +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_2_04: + case cJ1_JPIMMED_2_05: + case cJ1_JPIMMED_2_06: + case cJ1_JPIMMED_2_07: +#endif +#if (defined(JUDY1) || defined(JU_64BIT)) + *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: +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_3_03: + case cJ1_JPIMMED_3_04: + case cJ1_JPIMMED_3_05: +#endif +#if (defined(JUDY1) || defined(JU_64BIT)) + { + Word_t lsb; + 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: + case cJ1_JPIMMED_4_03: + + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(4))) + | ((uint32_t *) PJI)[offset]; + JU_RET_FOUND_IMM(Pjp, offset); + + case cJ1_JPIMMED_5_02: + case cJ1_JPIMMED_5_03: + { + Word_t lsb; + 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: + { + Word_t lsb; + 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: + { + Word_t lsb; + 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) + + } // switch for not-found *PIndex + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); // impossible? + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + +// ---------------------------------------------------------------------------- +// BITMAP LEAF: +// +// Check Decode bytes, if any, in the current JP, then look in the leaf for +// *PIndex. + + case cJU_JPLEAF_B1: + { + Pjlb_t Pjlb; + CHECKDCD(1); + + Pjlb = P_JLB(Pjp->jp_Addr); + digit = JU_DIGITATSTATE(*PIndex, 1); + subexp = JU_SUBEXPL(digit); + bitposmask = JU_BITPOSMASKL(digit); + assert(subexp < cJU_NUMSUBEXPL); // falls in expected range. + +// *PIndex exists in LeafB1: + +// if (JU_BITMAPTESTL(Pjlb, digit)) // slower. + if (JU_JLB_BITMAP(Pjlb, subexp) & bitposmask) // faster. + { +#ifdef JUDYL // needs offset at this point: + offset = SEARCHBITMAPL(JU_JLB_BITMAP(Pjlb, subexp), digit, bitposmask); +#endif + JU_RET_FOUND_LEAF_B1(Pjlb, subexp, offset); +// == return((PPvoid_t) (P_JV(JL_JLB_PVALUE(Pjlb, subexp)) + (offset))); + } + +// Dead end, no Index in LeafB1 for remaining digit in *PIndex: +// +// If theres a next-left/right Index in the current LeafB1, which for +// Judy*Next() is true if any bits are set for higher Indexes, shortcut by +// returning it. Note: For Judy*Prev(), offset is set here to the correct +// value for the next-left JP. + + offset = SEARCHBITMAPL(JU_JLB_BITMAP(Pjlb, subexp), digit, + bitposmask); + // right range: + assert((offset >= -1) && (offset < (int) cJU_BITSPERSUBEXPL)); + +#ifdef JUDYPREV + if (offset >= 0) // next-left JP is in this subexpanse. + goto SM1LeafB1Findlimit; + + while (--subexp >= 0) // search next-left subexpanses. +#else + if (JU_JLB_BITMAP(Pjlb, subexp) & JU_MASKHIGHEREXC(bitposmask)) + { + ++offset; // next-left => next-right. + goto SM1LeafB1Findlimit; + } + + while (++subexp < cJU_NUMSUBEXPL) // search next-right subexps. +#endif + { + if (! JU_JLB_BITMAP(Pjlb, subexp)) continue; // empty subexp. + +#ifdef JUDYPREV + offset = SEARCHBITMAPMAXL(JU_JLB_BITMAP(Pjlb, subexp)); + // expected range: + assert((offset >= 0) && (offset < (int) cJU_BITSPERSUBEXPL)); +#else + offset = 0; +#endif + +// Save the next-left/right Indexess digit in *PIndex: + +SM1LeafB1Findlimit: + 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))); + } + +// Theres no next-left/right Index in the LeafB1: +// +// Shortcut and start backtracking one level up; ignore the current Pjp because +// it points to a LeafB1 with no next-left/right Index. + + goto SM2Backtrack; + + } // case cJU_JPLEAF_B1 + +#ifdef JUDY1 +// ---------------------------------------------------------------------------- +// FULL POPULATION: +// +// If the Decode bytes match, *PIndex is found (without modification). + + case cJ1_JPFULLPOPU1: + + CHECKDCD(1); + JU_RET_FOUND_FULLPOPU1; +#endif + + +// ---------------------------------------------------------------------------- +// IMMEDIATE: + +#ifdef JUDYPREV +#define SM1IMM_SETPOP1(cPop1) +#else +#define SM1IMM_SETPOP1(cPop1) pop1 = (cPop1) +#endif + +#define SM1IMM(Func,cPop1) \ + SM1IMM_SETPOP1(cPop1); \ + offset = Func((Pjll_t) (PJI), cPop1, *PIndex); \ + goto SM1LeafLImm + +// Special case for Pop1 = 1 Immediate JPs: +// +// If *PIndex is in the immediate, offset is 0, otherwise the binary NOT of the +// offset where it belongs, 0 or 1, same as from the search functions. + +#ifdef JUDYPREV +#define SM1IMM_01_SETPOP1 +#else +#define SM1IMM_01_SETPOP1 pop1 = 1 +#endif + +#define SM1IMM_01 \ + SM1IMM_01_SETPOP1; \ + offset = ((JU_JPDCDPOP0(Pjp) < JU_TRIMTODCDSIZE(*PIndex)) ? ~1 : \ + (JU_JPDCDPOP0(Pjp) == JU_TRIMTODCDSIZE(*PIndex)) ? 0 : \ + ~0); \ + goto SM1LeafLImm + + case cJU_JPIMMED_1_01: + case cJU_JPIMMED_2_01: + case cJU_JPIMMED_3_01: +#ifdef JU_64BIT + case cJU_JPIMMED_4_01: + case cJU_JPIMMED_5_01: + case cJU_JPIMMED_6_01: + case cJU_JPIMMED_7_01: +#endif + SM1IMM_01; + +// TBD: Doug says it would be OK to have fewer calls and calculate arg 2, here +// and in Judy*Count() also. + + case cJU_JPIMMED_1_02: SM1IMM(j__udySearchLeaf1, 2); + case cJU_JPIMMED_1_03: SM1IMM(j__udySearchLeaf1, 3); +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_1_04: SM1IMM(j__udySearchLeaf1, 4); + case cJU_JPIMMED_1_05: SM1IMM(j__udySearchLeaf1, 5); + case cJU_JPIMMED_1_06: SM1IMM(j__udySearchLeaf1, 6); + case cJU_JPIMMED_1_07: SM1IMM(j__udySearchLeaf1, 7); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_1_08: SM1IMM(j__udySearchLeaf1, 8); + case cJ1_JPIMMED_1_09: SM1IMM(j__udySearchLeaf1, 9); + case cJ1_JPIMMED_1_10: SM1IMM(j__udySearchLeaf1, 10); + case cJ1_JPIMMED_1_11: SM1IMM(j__udySearchLeaf1, 11); + case cJ1_JPIMMED_1_12: SM1IMM(j__udySearchLeaf1, 12); + case cJ1_JPIMMED_1_13: SM1IMM(j__udySearchLeaf1, 13); + case cJ1_JPIMMED_1_14: SM1IMM(j__udySearchLeaf1, 14); + case cJ1_JPIMMED_1_15: SM1IMM(j__udySearchLeaf1, 15); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_2_02: SM1IMM(j__udySearchLeaf2, 2); + case cJU_JPIMMED_2_03: SM1IMM(j__udySearchLeaf2, 3); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_2_04: SM1IMM(j__udySearchLeaf2, 4); + case cJ1_JPIMMED_2_05: SM1IMM(j__udySearchLeaf2, 5); + case cJ1_JPIMMED_2_06: SM1IMM(j__udySearchLeaf2, 6); + case cJ1_JPIMMED_2_07: SM1IMM(j__udySearchLeaf2, 7); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_3_02: SM1IMM(j__udySearchLeaf3, 2); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_3_03: SM1IMM(j__udySearchLeaf3, 3); + case cJ1_JPIMMED_3_04: SM1IMM(j__udySearchLeaf3, 4); + case cJ1_JPIMMED_3_05: SM1IMM(j__udySearchLeaf3, 5); + + case cJ1_JPIMMED_4_02: SM1IMM(j__udySearchLeaf4, 2); + case cJ1_JPIMMED_4_03: SM1IMM(j__udySearchLeaf4, 3); + + case cJ1_JPIMMED_5_02: SM1IMM(j__udySearchLeaf5, 2); + case cJ1_JPIMMED_5_03: SM1IMM(j__udySearchLeaf5, 3); + + case cJ1_JPIMMED_6_02: SM1IMM(j__udySearchLeaf6, 2); + + case cJ1_JPIMMED_7_02: SM1IMM(j__udySearchLeaf7, 2); +#endif + + +// ---------------------------------------------------------------------------- +// INVALID JP TYPE: + + default: JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // SM1Get switch. + + /*NOTREACHED*/ + + +// ============================================================================ +// STATE MACHINE 2 -- BACKTRACK BRANCH TO PREVIOUS JP: +// +// Look for the next-left/right JP in a branch, backing up the history list as +// necessary. Upon finding a next-left/right JP, modify the corresponding +// digit in *PIndex before passing control to SM3Findlimit. +// +// Note: As described earlier, only branch JPs are expected here; other types +// fall into the default case. +// +// Note: If a found JP contains needed Dcd bytes, thats OK, theyre copied to +// *PIndex in SM3Findlimit. +// +// TBD: This code has a lot in common with similar code in the shortcut cases +// in SM1Get. Can combine this code somehow? +// +// ENTRY: List, possibly empty, of JPs and offsets in APjphist[] and +// Aoffhist[]; see earlier comments. +// +// EXIT: Execute JU_RET_NOTFOUND if no previous/next JP; otherwise jump to +// SM3Findlimit to resume a new but different downward search. + +SM2Backtrack: // come or return here for first/next sideways search. + + HISTPOP(Pjp, offset); + + switch (JU_JPTYPE(Pjp)) + { + + +// ---------------------------------------------------------------------------- +// LINEAR BRANCH: + + case cJU_JPBRANCH_L2: state = 2; goto SM2BranchL; + case cJU_JPBRANCH_L3: state = 3; goto SM2BranchL; +#ifdef JU_64BIT + case cJU_JPBRANCH_L4: state = 4; goto SM2BranchL; + case cJU_JPBRANCH_L5: state = 5; goto SM2BranchL; + case cJU_JPBRANCH_L6: state = 6; goto SM2BranchL; + case cJU_JPBRANCH_L7: state = 7; goto SM2BranchL; +#endif + case cJU_JPBRANCH_L: state = cJU_ROOTSTATE; goto SM2BranchL; + +SM2BranchL: +#ifdef JUDYPREV + if (--offset < 0) goto SM2Backtrack; // no next-left JP in BranchL. +#endif + Pjbl = P_JBL(Pjp->jp_Addr); +#ifdef JUDYNEXT + if (++offset >= (Pjbl->jbl_NumJPs)) goto SM2Backtrack; + // no next-right JP in BranchL. +#endif + +// Theres a next-left/right JP in the current BranchL; save its digit in +// *PIndex and continue with SM3Findlimit: + + JU_SETDIGIT(*PIndex, Pjbl->jbl_Expanse[offset], state); + Pjp = (Pjbl->jbl_jp) + offset; + goto SM3Findlimit; + + +// ---------------------------------------------------------------------------- +// BITMAP BRANCH: + + case cJU_JPBRANCH_B2: state = 2; goto SM2BranchB; + case cJU_JPBRANCH_B3: state = 3; goto SM2BranchB; +#ifdef JU_64BIT + case cJU_JPBRANCH_B4: state = 4; goto SM2BranchB; + case cJU_JPBRANCH_B5: state = 5; goto SM2BranchB; + case cJU_JPBRANCH_B6: state = 6; goto SM2BranchB; + case cJU_JPBRANCH_B7: state = 7; goto SM2BranchB; +#endif + case cJU_JPBRANCH_B: state = cJU_ROOTSTATE; goto SM2BranchB; + +SM2BranchB: + Pjbb = P_JBB(Pjp->jp_Addr); + HISTPOPBOFF(subexp, offset, digit); // unpack values. + +// If theres a next-left/right JP in the current BranchB, which for +// Judy*Next() is true if any bits are set for higher Indexes, continue to +// SM3Findlimit: +// +// Note: offset is set to the JP previously traversed; go one to the +// left/right. + +#ifdef JUDYPREV + if (offset > 0) // next-left JP is in this subexpanse. + { + --offset; + goto SM2BranchBFindlimit; + } + + while (--subexp >= 0) // search next-left subexpanses. +#else + if (JU_JBB_BITMAP(Pjbb, subexp) + & JU_MASKHIGHEREXC(JU_BITPOSMASKB(digit))) + { + ++offset; // next-left => next-right. + goto SM2BranchBFindlimit; + } + + while (++subexp < cJU_NUMSUBEXPB) // search next-right subexps. +#endif + { + if (! JU_JBB_PJP(Pjbb, subexp)) continue; // empty subexpanse. + +#ifdef JUDYPREV + offset = SEARCHBITMAPMAXB(JU_JBB_BITMAP(Pjbb, subexp)); + // expected range: + assert((offset >= 0) && (offset < cJU_BITSPERSUBEXPB)); +#else + offset = 0; +#endif + +// Save the next-left/right JPs digit in *PIndex: + +SM2BranchBFindlimit: + JU_BITMAPDIGITB(digit, subexp, JU_JBB_BITMAP(Pjbb, subexp), + offset); + JU_SETDIGIT(*PIndex, digit, state); + + if ((Pjp = P_JP(JU_JBB_PJP(Pjbb, subexp))) == (Pjp_t) NULL) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + + Pjp += offset; + goto SM3Findlimit; + } + +// Theres no next-left/right JP in the BranchB: + + goto SM2Backtrack; + + +// ---------------------------------------------------------------------------- +// UNCOMPRESSED BRANCH: + + case cJU_JPBRANCH_U2: state = 2; goto SM2BranchU; + case cJU_JPBRANCH_U3: state = 3; goto SM2BranchU; +#ifdef JU_64BIT + case cJU_JPBRANCH_U4: state = 4; goto SM2BranchU; + case cJU_JPBRANCH_U5: state = 5; goto SM2BranchU; + case cJU_JPBRANCH_U6: state = 6; goto SM2BranchU; + case cJU_JPBRANCH_U7: state = 7; goto SM2BranchU; +#endif + case cJU_JPBRANCH_U: state = cJU_ROOTSTATE; goto SM2BranchU; + +SM2BranchU: + +// Search for a next-left/right JP in the current BranchU, and if one is found, +// save its digit in *PIndex and continue to SM3Findlimit: + + Pjbu = P_JBU(Pjp->jp_Addr); + digit = offset; + +#ifdef JUDYPREV + while (digit >= 1) + { + Pjp = (Pjbu->jbu_jp) + (--digit); +#else + while (digit < cJU_BRANCHUNUMJPS - 1) + { + Pjp = (Pjbu->jbu_jp) + (++digit); +#endif + if (JPNULL(JU_JPTYPE(Pjp))) continue; + + JU_SETDIGIT(*PIndex, digit, state); + goto SM3Findlimit; + } + +// Theres no next-left/right JP in the BranchU: + + goto SM2Backtrack; + + +// ---------------------------------------------------------------------------- +// INVALID JP TYPE: + + default: JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // SM2Backtrack switch. + + /*NOTREACHED*/ + + +// ============================================================================ +// STATE MACHINE 3 -- FIND LIMIT JP/INDEX: +// +// Look for the highest/lowest (right/left-most) JP in each branch and the +// highest/lowest Index in a leaf or immediate, and return it. While +// traversing, modify appropriate digit(s) in *PIndex to reflect the path +// taken, including Dcd bytes in each JP (which could hold critical missing +// digits for skipped branches). +// +// ENTRY: Pjp set to a JP under which to find max/min JPs (if a branch JP) or +// a max/min Index and return (if a leaf or immediate JP). +// +// EXIT: Execute JU_RET_FOUND* upon reaching a leaf or immediate. Should be +// impossible to fail, unless the Judy array is corrupt. + +SM3Findlimit: // come or return here for first/next branch/leaf. + + switch (JU_JPTYPE(Pjp)) + { +// ---------------------------------------------------------------------------- +// LINEAR BRANCH: +// +// Simply use the highest/lowest (right/left-most) JP in the BranchL, but first +// copy the Dcd bytes to *PIndex if there are any (only if state < +// cJU_ROOTSTATE - 1). + + case cJU_JPBRANCH_L2: SM3PREPB_DCD(2, SM3BranchL); +#ifndef JU_64BIT + case cJU_JPBRANCH_L3: SM3PREPB( 3, SM3BranchL); +#else + case cJU_JPBRANCH_L3: SM3PREPB_DCD(3, SM3BranchL); + case cJU_JPBRANCH_L4: SM3PREPB_DCD(4, SM3BranchL); + case cJU_JPBRANCH_L5: SM3PREPB_DCD(5, SM3BranchL); + case cJU_JPBRANCH_L6: SM3PREPB_DCD(6, SM3BranchL); + case cJU_JPBRANCH_L7: SM3PREPB( 7, SM3BranchL); +#endif + case cJU_JPBRANCH_L: SM3PREPB( cJU_ROOTSTATE, SM3BranchL); + +SM3BranchL: + Pjbl = P_JBL(Pjp->jp_Addr); + +#ifdef JUDYPREV + if ((offset = (Pjbl->jbl_NumJPs) - 1) < 0) +#else + offset = 0; if ((Pjbl->jbl_NumJPs) == 0) +#endif + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + + JU_SETDIGIT(*PIndex, Pjbl->jbl_Expanse[offset], state); + Pjp = (Pjbl->jbl_jp) + offset; + goto SM3Findlimit; + + +// ---------------------------------------------------------------------------- +// BITMAP BRANCH: +// +// Look for the highest/lowest (right/left-most) non-null subexpanse, then use +// the highest/lowest JP in that subexpanse, but first copy Dcd bytes, if there +// are any (only if state < cJU_ROOTSTATE - 1), to *PIndex. + + case cJU_JPBRANCH_B2: SM3PREPB_DCD(2, SM3BranchB); +#ifndef JU_64BIT + case cJU_JPBRANCH_B3: SM3PREPB( 3, SM3BranchB); +#else + case cJU_JPBRANCH_B3: SM3PREPB_DCD(3, SM3BranchB); + case cJU_JPBRANCH_B4: SM3PREPB_DCD(4, SM3BranchB); + case cJU_JPBRANCH_B5: SM3PREPB_DCD(5, SM3BranchB); + case cJU_JPBRANCH_B6: SM3PREPB_DCD(6, SM3BranchB); + case cJU_JPBRANCH_B7: SM3PREPB( 7, SM3BranchB); +#endif + case cJU_JPBRANCH_B: SM3PREPB( cJU_ROOTSTATE, SM3BranchB); + +SM3BranchB: + Pjbb = P_JBB(Pjp->jp_Addr); +#ifdef JUDYPREV + subexp = cJU_NUMSUBEXPB; + + while (! (JU_JBB_BITMAP(Pjbb, --subexp))) // find non-empty subexp. + { + if (subexp <= 0) // wholly empty bitmap. + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + } + + offset = SEARCHBITMAPMAXB(JU_JBB_BITMAP(Pjbb, subexp)); + // expected range: + assert((offset >= 0) && (offset < cJU_BITSPERSUBEXPB)); +#else + subexp = -1; + + while (! (JU_JBB_BITMAP(Pjbb, ++subexp))) // find non-empty subexp. + { + if (subexp >= cJU_NUMSUBEXPB - 1) // didnt find one. + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + } + + offset = 0; +#endif + + JU_BITMAPDIGITB(digit, subexp, JU_JBB_BITMAP(Pjbb, subexp), offset); + JU_SETDIGIT(*PIndex, digit, state); + + if ((Pjp = P_JP(JU_JBB_PJP(Pjbb, subexp))) == (Pjp_t) NULL) + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + + Pjp += offset; + goto SM3Findlimit; + + +// ---------------------------------------------------------------------------- +// UNCOMPRESSED BRANCH: +// +// Look for the highest/lowest (right/left-most) non-null JP, and use it, but +// first copy Dcd bytes to *PIndex if there are any (only if state < +// cJU_ROOTSTATE - 1). + + case cJU_JPBRANCH_U2: SM3PREPB_DCD(2, SM3BranchU); +#ifndef JU_64BIT + case cJU_JPBRANCH_U3: SM3PREPB( 3, SM3BranchU); +#else + case cJU_JPBRANCH_U3: SM3PREPB_DCD(3, SM3BranchU); + case cJU_JPBRANCH_U4: SM3PREPB_DCD(4, SM3BranchU); + case cJU_JPBRANCH_U5: SM3PREPB_DCD(5, SM3BranchU); + case cJU_JPBRANCH_U6: SM3PREPB_DCD(6, SM3BranchU); + case cJU_JPBRANCH_U7: SM3PREPB( 7, SM3BranchU); +#endif + case cJU_JPBRANCH_U: SM3PREPB( cJU_ROOTSTATE, SM3BranchU); + +SM3BranchU: + Pjbu = P_JBU(Pjp->jp_Addr); +#ifdef JUDYPREV + digit = cJU_BRANCHUNUMJPS; + + while (digit >= 1) + { + Pjp = (Pjbu->jbu_jp) + (--digit); +#else + + for (digit = 0; digit < cJU_BRANCHUNUMJPS; ++digit) + { + Pjp = (Pjbu->jbu_jp) + digit; +#endif + if (JPNULL(JU_JPTYPE(Pjp))) continue; + + JU_SETDIGIT(*PIndex, digit, state); + goto SM3Findlimit; + } + +// No non-null JPs in BranchU: + + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + +// ---------------------------------------------------------------------------- +// LINEAR LEAF: +// +// Simply use the highest/lowest (right/left-most) Index in the LeafL, but the +// details vary depending on leaf Index Size. First copy Dcd bytes, if there +// are any (only if state < cJU_ROOTSTATE - 1), to *PIndex. + +#define SM3LEAFLDCD(cState) \ + JU_SETDCD(*PIndex, Pjp, cState); \ + SM3LEAFLNODCD + +#ifdef JUDY1 +#define SM3LEAFL_SETPOP1 // not needed in any cases. +#else +#define SM3LEAFL_SETPOP1 pop1 = JU_JPLEAF_POP0(Pjp) + 1 +#endif + +#ifdef JUDYPREV +#define SM3LEAFLNODCD \ + Pjll = P_JLL(Pjp->jp_Addr); \ + SM3LEAFL_SETPOP1; \ + offset = JU_JPLEAF_POP0(Pjp); assert(offset >= 0) +#else +#define SM3LEAFLNODCD \ + Pjll = P_JLL(Pjp->jp_Addr); \ + SM3LEAFL_SETPOP1; \ + offset = 0; assert(JU_JPLEAF_POP0(Pjp) >= 0); +#endif + +#if (defined(JUDYL) || (! defined(JU_64BIT))) + case cJU_JPLEAF1: + + SM3LEAFLDCD(1); + JU_SETDIGIT1(*PIndex, ((uint8_t *) Pjll)[offset]); + JU_RET_FOUND_LEAF1(Pjll, pop1, offset); +#endif + + case cJU_JPLEAF2: + + SM3LEAFLDCD(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; + SM3LEAFLNODCD; + 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; + SM3LEAFLDCD(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: + + SM3LEAFLDCD(4); + *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(4))) + | ((uint32_t *) Pjll)[offset]; + JU_RET_FOUND_LEAF4(Pjll, pop1, offset); + + case cJU_JPLEAF5: + { + Word_t lsb; + SM3LEAFLDCD(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; + SM3LEAFLDCD(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; + SM3LEAFLNODCD; + 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: +// +// Look for the highest/lowest (right/left-most) non-null subexpanse, then use +// the highest/lowest Index in that subexpanse, but first copy Dcd bytes +// (always present since state 1 < cJU_ROOTSTATE) to *PIndex. + + case cJU_JPLEAF_B1: + { + Pjlb_t Pjlb; + + JU_SETDCD(*PIndex, Pjp, 1); + + Pjlb = P_JLB(Pjp->jp_Addr); +#ifdef JUDYPREV + subexp = cJU_NUMSUBEXPL; + + while (! JU_JLB_BITMAP(Pjlb, --subexp)) // find non-empty subexp. + { + if (subexp <= 0) // wholly empty bitmap. + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + } + +// TBD: Might it be faster to just use a variant of BITMAPDIGIT*() that yields +// the digit for the right-most Index with a bit set? + + offset = SEARCHBITMAPMAXL(JU_JLB_BITMAP(Pjlb, subexp)); + // expected range: + assert((offset >= 0) && (offset < cJU_BITSPERSUBEXPL)); +#else + subexp = -1; + + while (! JU_JLB_BITMAP(Pjlb, ++subexp)) // find non-empty subexp. + { + if (subexp >= cJU_NUMSUBEXPL - 1) // didnt find one. + { + JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + } + } + + offset = 0; +#endif + + 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 to *PIndex (always present since state 1 < cJU_ROOTSTATE), +// then set the highest/lowest possible digit as the LSB in *PIndex. + + case cJ1_JPFULLPOPU1: + + JU_SETDCD( *PIndex, Pjp, 1); +#ifdef JUDYPREV + JU_SETDIGIT1(*PIndex, cJU_BITSPERBITMAP - 1); +#else + JU_SETDIGIT1(*PIndex, 0); +#endif + JU_RET_FOUND_FULLPOPU1; +#endif // JUDY1 + + +// ---------------------------------------------------------------------------- +// IMMEDIATE: +// +// Simply use the highest/lowest (right/left-most) Index in the Imm, but the +// details vary 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. + + case cJU_JPIMMED_1_01: SET_01(1); goto SM3Imm_01; + case cJU_JPIMMED_2_01: SET_01(2); goto SM3Imm_01; + case cJU_JPIMMED_3_01: SET_01(3); goto SM3Imm_01; +#ifdef JU_64BIT + case cJU_JPIMMED_4_01: SET_01(4); goto SM3Imm_01; + case cJU_JPIMMED_5_01: SET_01(5); goto SM3Imm_01; + case cJU_JPIMMED_6_01: SET_01(6); goto SM3Imm_01; + case cJU_JPIMMED_7_01: SET_01(7); goto SM3Imm_01; +#endif +SM3Imm_01: JU_RET_FOUND_IMM_01(Pjp); + +#ifdef JUDYPREV +#define SM3IMM_OFFSET(cPop1) (cPop1) - 1 // highest. +#else +#define SM3IMM_OFFSET(cPop1) 0 // lowest. +#endif + +#define SM3IMM(cPop1,Next) \ + offset = SM3IMM_OFFSET(cPop1); \ + goto Next + + case cJU_JPIMMED_1_02: SM3IMM( 2, SM3Imm1); + case cJU_JPIMMED_1_03: SM3IMM( 3, SM3Imm1); +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_1_04: SM3IMM( 4, SM3Imm1); + case cJU_JPIMMED_1_05: SM3IMM( 5, SM3Imm1); + case cJU_JPIMMED_1_06: SM3IMM( 6, SM3Imm1); + case cJU_JPIMMED_1_07: SM3IMM( 7, SM3Imm1); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_1_08: SM3IMM( 8, SM3Imm1); + case cJ1_JPIMMED_1_09: SM3IMM( 9, SM3Imm1); + case cJ1_JPIMMED_1_10: SM3IMM(10, SM3Imm1); + case cJ1_JPIMMED_1_11: SM3IMM(11, SM3Imm1); + case cJ1_JPIMMED_1_12: SM3IMM(12, SM3Imm1); + case cJ1_JPIMMED_1_13: SM3IMM(13, SM3Imm1); + case cJ1_JPIMMED_1_14: SM3IMM(14, SM3Imm1); + case cJ1_JPIMMED_1_15: SM3IMM(15, SM3Imm1); +#endif + +SM3Imm1: JU_SETDIGIT1(*PIndex, ((uint8_t *) PJI)[offset]); + JU_RET_FOUND_IMM(Pjp, offset); + +#if (defined(JUDY1) || defined(JU_64BIT)) + case cJU_JPIMMED_2_02: SM3IMM(2, SM3Imm2); + case cJU_JPIMMED_2_03: SM3IMM(3, SM3Imm2); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_2_04: SM3IMM(4, SM3Imm2); + case cJ1_JPIMMED_2_05: SM3IMM(5, SM3Imm2); + case cJ1_JPIMMED_2_06: SM3IMM(6, SM3Imm2); + case cJ1_JPIMMED_2_07: SM3IMM(7, SM3Imm2); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) +SM3Imm2: *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: SM3IMM(2, SM3Imm3); +#endif +#if (defined(JUDY1) && defined(JU_64BIT)) + case cJ1_JPIMMED_3_03: SM3IMM(3, SM3Imm3); + case cJ1_JPIMMED_3_04: SM3IMM(4, SM3Imm3); + case cJ1_JPIMMED_3_05: SM3IMM(5, SM3Imm3); +#endif + +#if (defined(JUDY1) || defined(JU_64BIT)) +SM3Imm3: + { + Word_t lsb; + 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: SM3IMM(2, SM3Imm4); + case cJ1_JPIMMED_4_03: SM3IMM(3, SM3Imm4); + +SM3Imm4: *PIndex = (*PIndex & (~JU_LEASTBYTESMASK(4))) + | ((uint32_t *) PJI)[offset]; + JU_RET_FOUND_IMM(Pjp, offset); + + case cJ1_JPIMMED_5_02: SM3IMM(2, SM3Imm5); + case cJ1_JPIMMED_5_03: SM3IMM(3, SM3Imm5); + +SM3Imm5: + { + Word_t lsb; + 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: SM3IMM(2, SM3Imm6); + +SM3Imm6: + { + Word_t lsb; + 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: SM3IMM(2, SM3Imm7); + +SM3Imm7: + { + Word_t lsb; + 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) + + +// ---------------------------------------------------------------------------- +// OTHER CASES: + + default: JU_SET_ERRNO(PJError, JU_ERRNO_CORRUPT); + JUDY1CODE(return(JERRI );) + JUDYLCODE(return(PPJERR);) + + } // SM3Findlimit switch. + + /*NOTREACHED*/ + +} // Judy1Prev() / Judy1Next() / JudyLPrev() / JudyLNext() -- cgit v1.2.3