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Diffstat (limited to 'libnetdata/libjudy/src/JudyCommon/JudyPrivateBranch.h')
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diff --git a/libnetdata/libjudy/src/JudyCommon/JudyPrivateBranch.h b/libnetdata/libjudy/src/JudyCommon/JudyPrivateBranch.h new file mode 100644 index 00000000..10295ba9 --- /dev/null +++ b/libnetdata/libjudy/src/JudyCommon/JudyPrivateBranch.h @@ -0,0 +1,788 @@ +#ifndef _JUDY_PRIVATE_BRANCH_INCLUDED +#define _JUDY_PRIVATE_BRANCH_INCLUDED +// _________________ +// +// 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: 1.2 $ $Source: /home/doug/judy-1.0.5_min/test/../src/JudyCommon/RCS/JudyPrivateBranch.h,v $ +// +// Header file for all Judy sources, for global but private (non-exported) +// declarations specific to branch support. +// +// See also the "Judy Shop Manual" (try judy/doc/int/JudyShopManual.*). + + +// **************************************************************************** +// JUDY POINTER (JP) SUPPORT +// **************************************************************************** +// +// This "rich pointer" object is pivotal to Judy execution. +// +// JP CONTAINING OTHER THAN IMMEDIATE INDEXES: +// +// If the JP points to a linear or bitmap leaf, jp_DcdPopO contains the +// Population-1 in LSbs and Decode (Dcd) bytes in the MSBs. (In practice the +// Decode bits are masked off while accessing the Pop0 bits.) +// +// The Decode Size, the number of Dcd bytes available, is encoded in jpo_Type. +// It can also be thought of as the number of states "skipped" in the SM, where +// each state decodes 8 bits = 1 byte. +// +// TBD: Dont need two structures, except possibly to force jp_Type to highest +// address! +// +// Note: The jpo_u union is not required by HP-UX or Linux but Win32 because +// the cl.exe compiler otherwise refuses to pack a bitfield (DcdPopO) with +// anything else, even with the -Zp option. This is pretty ugly, but +// fortunately portable, and its all hide-able by macros (see below). + +typedef struct J_UDY_POINTER_OTHERS // JPO. + { + Word_t j_po_Addr; // first word: Pjp_t, Word_t, etc. + union { + Word_t j_po_Addr1; + uint8_t j_po_DcdP0[sizeof(Word_t) - 1]; + uint8_t j_po_Bytes[sizeof(Word_t)]; // last byte = jp_Type. + } jpo_u; + } jpo_t; + + +// JP CONTAINING IMMEDIATE INDEXES: +// +// j_pi_1Index[] plus j_pi_LIndex[] together hold as many N-byte (1..3-byte +// [1..7-byte]) Indexes as will fit in sizeof(jpi_t) less 1 byte for j_pi_Type +// (that is, 7..1 [15..1] Indexes). +// +// For Judy1, j_pi_1Index[] is used and j_pi_LIndex[] is not used. +// For JudyL, j_pi_LIndex[] is used and j_pi_1Index[] is not used. +// +// Note: Actually when Pop1 = 1, jpi_t is not used, and the least bytes of the +// single Index are stored in j_po_DcdPopO, for both Judy1 and JudyL, so for +// JudyL the j_po_Addr field can hold the target value. +// +// TBD: Revise this structure to not overload j_po_DcdPopO this way? The +// current arrangement works, its just confusing. + +typedef struct _JUDY_POINTER_IMMEDL + { + Word_t j_pL_Addr; + uint8_t j_pL_LIndex[sizeof(Word_t) - 1]; // see above. + uint8_t j_pL_Type; + } jpL_t; + +typedef struct _JUDY_POINTER_IMMED1 + { + uint8_t j_p1_1Index[(2 * sizeof(Word_t)) - 1]; + uint8_t j_p1_Type; + } jp1_t; + +// UNION OF JP TYPES: +// +// A branch is an array of cJU_BRANCHUNUMJPS (256) of this object, or an +// alternate data type such as: A linear branch which is a list of 2..7 JPs, +// or a bitmap branch which contains 8 lists of 0..32 JPs. JPs reside only in +// branches of a Judy SM. + +typedef union J_UDY_POINTER // JP. + { + jpo_t j_po; // other than immediate indexes. + jpL_t j_pL; // immediate indexes. + jp1_t j_p1; // immediate indexes. + } jp_t, *Pjp_t; + +// For coding convenience: +// +// Note, jp_Type has the same bits in jpo_t jpL_t and jp1_t. + +#define jp_1Index j_p1.j_p1_1Index // for storing Indexes in first word. +#define jp_LIndex j_pL.j_pL_LIndex // for storing Indexes in second word. +#define jp_Addr j_po.j_po_Addr +#define jp_Addr1 j_po.jpo_u.j_po_Addr1 +//#define jp_DcdPop0 j_po.jpo_u.j_po_DcdPop0 +#define jp_Addr1 j_po.jpo_u.j_po_Addr1 +//#define jp_Type j_po.jpo_u.j_po_Bytes[sizeof(Word_t) - 1] +#define jp_Type j_p1.j_p1_Type +#define jp_DcdP0 j_po.jpo_u.j_po_DcdP0 + + +// **************************************************************************** +// JUDY POINTER (JP) -- RELATED MACROS AND CONSTANTS +// **************************************************************************** + +// EXTRACT VALUES FROM JP: +// +// Masks for the bytes in the Dcd and Pop0 parts of jp_DcdPopO: +// +// cJU_DCDMASK() consists of a mask that excludes the (LSb) Pop0 bytes and +// also, just to be safe, the top byte of the word, since jp_DcdPopO is 1 byte +// less than a full word. +// +// Note: These are constant macros (cJU) because cPopBytes should be a +// constant. Also note cPopBytes == state in the SM. + +#define cJU_POP0MASK(cPopBytes) JU_LEASTBYTESMASK(cPopBytes) + +#define cJU_DCDMASK(cPopBytes) \ + ((cJU_ALLONES >> cJU_BITSPERBYTE) & (~cJU_POP0MASK(cPopBytes))) + +// Mask off the high byte from INDEX to it can be compared to DcdPopO: + +#define JU_TRIMTODCDSIZE(INDEX) ((cJU_ALLONES >> cJU_BITSPERBYTE) & (INDEX)) + +// Get from jp_DcdPopO the Pop0 for various branch JP Types: +// +// Note: There are no simple macros for cJU_BRANCH* Types because their +// populations must be added up and dont reside in an already-calculated +// place. + +#define JU_JPBRANCH_POP0(PJP,cPopBytes) \ + (JU_JPDCDPOP0(PJP) & cJU_POP0MASK(cPopBytes)) + +// METHOD FOR DETERMINING IF OBJECTS HAVE ROOM TO GROW: +// +// J__U_GROWCK() is a generic method to determine if an object can grow in +// place, based on whether the next population size (one more) would use the +// same space. + +#define J__U_GROWCK(POP1,MAXPOP1,POPTOWORDS) \ + (((POP1) != (MAXPOP1)) && (POPTOWORDS[POP1] == POPTOWORDS[(POP1) + 1])) + +#define JU_BRANCHBJPGROWINPLACE(NumJPs) \ + J__U_GROWCK(NumJPs, cJU_BITSPERSUBEXPB, j__U_BranchBJPPopToWords) + + +// DETERMINE IF AN INDEX IS (NOT) IN A JPS EXPANSE: + +#define JU_DCDNOTMATCHINDEX(INDEX,PJP,POP0BYTES) \ + (((INDEX) ^ JU_JPDCDPOP0(PJP)) & cJU_DCDMASK(POP0BYTES)) + + +// NUMBER OF JPs IN AN UNCOMPRESSED BRANCH: +// +// An uncompressed branch is simply an array of 256 Judy Pointers (JPs). It is +// a minimum cacheline fill object. Define it here before its first needed. + +#define cJU_BRANCHUNUMJPS cJU_SUBEXPPERSTATE + + +// **************************************************************************** +// JUDY BRANCH LINEAR (JBL) SUPPORT +// **************************************************************************** +// +// A linear branch is a way of compressing empty expanses (null JPs) out of an +// uncompressed 256-way branch, when the number of populated expanses is so +// small that even a bitmap branch is excessive. +// +// The maximum number of JPs in a Judy linear branch: +// +// Note: This number results in a 1-cacheline sized structure. Previous +// versions had a larger struct so a linear branch didnt become a bitmap +// branch until the memory consumed was even, but for speed, its better to +// switch "sooner" and keep a linear branch fast. + +#define cJU_BRANCHLMAXJPS 7 + + +// LINEAR BRANCH STRUCT: +// +// 1-byte count, followed by array of byte-sized expanses, followed by JPs. + +typedef struct J__UDY_BRANCH_LINEAR + { + uint8_t jbl_NumJPs; // num of JPs (Pjp_t), 1..N. + uint8_t jbl_Expanse[cJU_BRANCHLMAXJPS]; // 1..7 MSbs of pop exps. + jp_t jbl_jp [cJU_BRANCHLMAXJPS]; // JPs for populated exps. + } jbl_t, * Pjbl_t; + + +// **************************************************************************** +// JUDY BRANCH BITMAP (JBB) SUPPORT +// **************************************************************************** +// +// A bitmap branch is a way of compressing empty expanses (null JPs) out of +// uncompressed 256-way branch. This costs 1 additional cache line fill, but +// can save a lot of memory when it matters most, near the leaves, and +// typically there will be only one at most in the path to any Index (leaf). +// +// The bitmap indicates which of the cJU_BRANCHUNUMJPS (256) JPs in the branch +// are NOT null, that is, their expanses are populated. The jbb_t also +// contains N pointers to "mini" Judy branches ("subexpanses") of up to M JPs +// each (see BITMAP_BRANCHMxN, for example, BITMAP_BRANCH32x8), where M x N = +// cJU_BRANCHUNUMJPS. These are dynamically allocated and never contain +// cJ*_JPNULL* jp_Types. An empty subexpanse is represented by no bit sets in +// the corresponding subexpanse bitmap, in which case the corresponding +// jbbs_Pjp pointers value is unused. +// +// Note that the number of valid JPs in each 1-of-N subexpanses is determined +// by POPULATION rather than by EXPANSE -- the desired outcome to save memory +// when near the leaves. Note that the memory required for 185 JPs is about as +// much as an uncompressed 256-way branch, therefore 184 is set as the maximum. +// However, it is expected that a conversion to an uncompressed 256-way branch +// will normally take place before this limit is reached for other reasons, +// such as improving performance when the "wasted" memory is well amortized by +// the population under the branch, preserving an acceptable overall +// bytes/Index in the Judy array. +// +// The number of pointers to arrays of JPs in the Judy bitmap branch: +// +// Note: The numbers below are the same in both 32 and 64 bit systems. + +#define cJU_BRANCHBMAXJPS 184 // maximum JPs for bitmap branches. + +// Convenience wrappers for referencing BranchB bitmaps or JP subarray +// pointers: +// +// Note: JU_JBB_PJP produces a "raw" memory address that must pass through +// P_JP before use, except when freeing memory: + +#define JU_JBB_BITMAP(Pjbb, SubExp) ((Pjbb)->jbb_jbbs[SubExp].jbbs_Bitmap) +#define JU_JBB_PJP( Pjbb, SubExp) ((Pjbb)->jbb_jbbs[SubExp].jbbs_Pjp) + +#define JU_SUBEXPB(Digit) (((Digit) / cJU_BITSPERSUBEXPB) & (cJU_NUMSUBEXPB-1)) + +#define JU_BITMAPTESTB(Pjbb, Index) \ + (JU_JBB_BITMAP(Pjbb, JU_SUBEXPB(Index)) & JU_BITPOSMASKB(Index)) + +#define JU_BITMAPSETB(Pjbb, Index) \ + (JU_JBB_BITMAP(Pjbb, JU_SUBEXPB(Index)) |= JU_BITPOSMASKB(Index)) + +// Note: JU_BITMAPCLEARB is not defined because the code does it a faster way. + +typedef struct J__UDY_BRANCH_BITMAP_SUBEXPANSE + { + BITMAPB_t jbbs_Bitmap; + Pjp_t jbbs_Pjp; + + } jbbs_t; + +typedef struct J__UDY_BRANCH_BITMAP + { + jbbs_t jbb_jbbs [cJU_NUMSUBEXPB]; +#ifdef SUBEXPCOUNTS + Word_t jbb_subPop1[cJU_NUMSUBEXPB]; +#endif + } jbb_t, * Pjbb_t; + +#define JU_BRANCHJP_NUMJPSTOWORDS(NumJPs) (j__U_BranchBJPPopToWords[NumJPs]) + +#ifdef SUBEXPCOUNTS +#define cJU_NUMSUBEXPU 16 // number of subexpanse counts. +#endif + + +// **************************************************************************** +// JUDY BRANCH UNCOMPRESSED (JBU) SUPPORT +// **************************************************************************** + +// Convenience wrapper for referencing BranchU JPs: +// +// Note: This produces a non-"raw" address already passed through P_JBU(). + +#define JU_JBU_PJP(Pjp,Index,Level) \ + (&((P_JBU((Pjp)->jp_Addr))->jbu_jp[JU_DIGITATSTATE(Index, Level)])) +#define JU_JBU_PJP0(Pjp) \ + (&((P_JBU((Pjp)->jp_Addr))->jbu_jp[0])) + +typedef struct J__UDY_BRANCH_UNCOMPRESSED + { + jp_t jbu_jp [cJU_BRANCHUNUMJPS]; // JPs for populated exp. +#ifdef SUBEXPCOUNTS + Word_t jbu_subPop1[cJU_NUMSUBEXPU]; +#endif + } jbu_t, * Pjbu_t; + + +// **************************************************************************** +// OTHER SUPPORT FOR JUDY STATE MACHINES (SMs) +// **************************************************************************** + +// OBJECT SIZES IN WORDS: +// +// Word_ts per various JudyL structures that have constant sizes. +// cJU_WORDSPERJP should always be 2; this is fundamental to the Judy +// structures. + +#define cJU_WORDSPERJP (sizeof(jp_t) / cJU_BYTESPERWORD) +#define cJU_WORDSPERCL (cJU_BYTESPERCL / cJU_BYTESPERWORD) + + +// OPPORTUNISTIC UNCOMPRESSION: +// +// Define populations at which a BranchL or BranchB must convert to BranchU. +// Earlier conversion is possible with good memory efficiency -- see below. + +#ifndef NO_BRANCHU + +// Max population below BranchL, then convert to BranchU: + +#define JU_BRANCHL_MAX_POP 1000 + +// Minimum global population increment before next conversion of a BranchB to a +// BranchU: +// +// This is was done to allow malloc() to coalesce memory before the next big +// (~512 words) allocation. + +#define JU_BTOU_POP_INCREMENT 300 + +// Min/max population below BranchB, then convert to BranchU: + +#define JU_BRANCHB_MIN_POP 135 +#define JU_BRANCHB_MAX_POP 750 + +#else // NO_BRANCHU + +// These are set up to have conservative conversion schedules to BranchU: + +#define JU_BRANCHL_MAX_POP (-1UL) +#define JU_BTOU_POP_INCREMENT 300 +#define JU_BRANCHB_MIN_POP 1000 +#define JU_BRANCHB_MAX_POP (-1UL) + +#endif // NO_BRANCHU + + +// MISCELLANEOUS MACROS: + +// Get N most significant bits from the shifted Index word: +// +// As Index words are decoded, they are shifted left so only relevant, +// undecoded Index bits remain. + +#define JU_BITSFROMSFTIDX(SFTIDX, N) ((SFTIDX) >> (cJU_BITSPERWORD - (N))) + +// TBD: I have my doubts about the necessity of these macros (dlb): + +// Produce 1-digit mask at specified state: + +#define cJU_MASKATSTATE(State) (0xffL << (((State) - 1) * cJU_BITSPERBYTE)) + +// Get byte (digit) from Index at the specified state, right justified: +// +// Note: State must be 1..cJU_ROOTSTATE, and Digits must be 1..(cJU_ROOTSTATE +// - 1), but theres no way to assert these within an expression. + +#define JU_DIGITATSTATE(Index,cState) \ + ((uint8_t)((Index) >> (((cState) - 1) * cJU_BITSPERBYTE))) + +// Similarly, place byte (digit) at correct position for the specified state: +// +// Note: Cast digit to a Word_t first so there are no complaints or problems +// about shifting it more than 32 bits on a 64-bit system, say, when it is a +// uint8_t from jbl_Expanse[]. (Believe it or not, the C standard says to +// promote an unsigned char to a signed int; -Ac does not do this, but -Ae +// does.) +// +// Also, to make lint happy, cast the whole result again because apparently +// shifting a Word_t does not result in a Word_t! + +#define JU_DIGITTOSTATE(Digit,cState) \ + ((Word_t) (((Word_t) (Digit)) << (((cState) - 1) * cJU_BITSPERBYTE))) + +#endif // ! _JUDY_PRIVATE_BRANCH_INCLUDED + + +#ifdef TEST_INSDEL + +// **************************************************************************** +// TEST CODE FOR INSERT/DELETE MACROS +// **************************************************************************** +// +// To use this, compile a temporary *.c file containing: +// +// #define DEBUG +// #define JUDY_ASSERT +// #define TEST_INSDEL +// #include "JudyPrivate.h" +// #include "JudyPrivateBranch.h" +// +// Use a command like this: cc -Ae +DD64 -I. -I JudyCommon -o t t.c +// For best results, include +DD64 on a 64-bit system. +// +// This test code exercises some tricky macros, but the output must be studied +// manually to verify it. Assume that for even-index testing, whole words +// (Word_t) suffices. + +#include <stdio.h> + +#define INDEXES 3 // in each array. + + +// **************************************************************************** +// I N I T +// +// Set up variables for next test. See usage. + +FUNCTION void Init ( + int base, + PWord_t PeIndex, + PWord_t PoIndex, + PWord_t Peleaf, // always whole words. +#ifndef JU_64BIT + uint8_t * Poleaf3) +#else + uint8_t * Poleaf3, + uint8_t * Poleaf5, + uint8_t * Poleaf6, + uint8_t * Poleaf7) +#endif +{ + int offset; + + *PeIndex = 99; + + for (offset = 0; offset <= INDEXES; ++offset) + Peleaf[offset] = base + offset; + + for (offset = 0; offset < (INDEXES + 1) * 3; ++offset) + Poleaf3[offset] = base + offset; + +#ifndef JU_64BIT + *PoIndex = (91 << 24) | (92 << 16) | (93 << 8) | 94; +#else + + *PoIndex = (91L << 56) | (92L << 48) | (93L << 40) | (94L << 32) + | (95L << 24) | (96L << 16) | (97L << 8) | 98L; + + for (offset = 0; offset < (INDEXES + 1) * 5; ++offset) + Poleaf5[offset] = base + offset; + + for (offset = 0; offset < (INDEXES + 1) * 6; ++offset) + Poleaf6[offset] = base + offset; + + for (offset = 0; offset < (INDEXES + 1) * 7; ++offset) + Poleaf7[offset] = base + offset; +#endif + +} // Init() + + +// **************************************************************************** +// P R I N T L E A F +// +// Print the byte values in a leaf. + +FUNCTION void PrintLeaf ( + char * Label, // for output. + int IOffset, // insertion offset in array. + int Indsize, // index size in bytes. + uint8_t * PLeaf) // array of Index bytes. +{ + int offset; // in PLeaf. + int byte; // in one word. + + (void) printf("%s %u: ", Label, IOffset); + + for (offset = 0; offset <= INDEXES; ++offset) + { + for (byte = 0; byte < Indsize; ++byte) + (void) printf("%2d", PLeaf[(offset * Indsize) + byte]); + + (void) printf(" "); + } + + (void) printf("\n"); + +} // PrintLeaf() + + +// **************************************************************************** +// M A I N +// +// Test program. + +FUNCTION main() +{ + Word_t eIndex; // even, to insert. + Word_t oIndex; // odd, to insert. + Word_t eleaf [ INDEXES + 1]; // even leaf, index size 4. + uint8_t oleaf3[(INDEXES + 1) * 3]; // odd leaf, index size 3. +#ifdef JU_64BIT + uint8_t oleaf5[(INDEXES + 1) * 5]; // odd leaf, index size 5. + uint8_t oleaf6[(INDEXES + 1) * 6]; // odd leaf, index size 6. + uint8_t oleaf7[(INDEXES + 1) * 7]; // odd leaf, index size 7. +#endif + Word_t eleaf_2 [ INDEXES + 1]; // same, but second arrays: + uint8_t oleaf3_2[(INDEXES + 1) * 3]; +#ifdef JU_64BIT + uint8_t oleaf5_2[(INDEXES + 1) * 5]; + uint8_t oleaf6_2[(INDEXES + 1) * 6]; + uint8_t oleaf7_2[(INDEXES + 1) * 7]; +#endif + int ioffset; // index insertion offset. + +#ifndef JU_64BIT +#define INIT Init( 0, & eIndex, & oIndex, eleaf, oleaf3) +#define INIT2 INIT; Init(50, & eIndex, & oIndex, eleaf_2, oleaf3_2) +#else +#define INIT Init( 0, & eIndex, & oIndex, eleaf, oleaf3, \ + oleaf5, oleaf6, oleaf7) +#define INIT2 INIT; Init(50, & eIndex, & oIndex, eleaf_2, oleaf3_2, \ + oleaf5_2, oleaf6_2, oleaf7_2) +#endif + +#define WSIZE sizeof (Word_t) // shorthand. + +#ifdef PRINTALL // to turn on "noisy" printouts. +#define PRINTLEAF(Label,IOffset,Indsize,PLeaf) \ + PrintLeaf(Label,IOffset,Indsize,PLeaf) +#else +#define PRINTLEAF(Label,IOffset,Indsize,PLeaf) \ + if (ioffset == 0) \ + PrintLeaf(Label,IOffset,Indsize,PLeaf) +#endif + + (void) printf( +"In each case, tests operate on an initial array of %d indexes. Even-index\n" +"tests set index values to 0,1,2...; odd-index tests set byte values to\n" +"0,1,2... Inserted indexes have a value of 99 or else byte values 91,92,...\n", + INDEXES); + + (void) puts("\nJU_INSERTINPLACE():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, WSIZE, (uint8_t *) eleaf); + JU_INSERTINPLACE(eleaf, INDEXES, ioffset, eIndex); + PrintLeaf("After ", ioffset, WSIZE, (uint8_t *) eleaf); + } + + (void) puts("\nJU_INSERTINPLACE3():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 3, oleaf3); + JU_INSERTINPLACE3(oleaf3, INDEXES, ioffset, oIndex); + PrintLeaf("After ", ioffset, 3, oleaf3); + } + +#ifdef JU_64BIT + (void) puts("\nJU_INSERTINPLACE5():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 5, oleaf5); + JU_INSERTINPLACE5(oleaf5, INDEXES, ioffset, oIndex); + PrintLeaf("After ", ioffset, 5, oleaf5); + } + + (void) puts("\nJU_INSERTINPLACE6():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 6, oleaf6); + JU_INSERTINPLACE6(oleaf6, INDEXES, ioffset, oIndex); + PrintLeaf("After ", ioffset, 6, oleaf6); + } + + (void) puts("\nJU_INSERTINPLACE7():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 7, oleaf7); + JU_INSERTINPLACE7(oleaf7, INDEXES, ioffset, oIndex); + PrintLeaf("After ", ioffset, 7, oleaf7); + } +#endif // JU_64BIT + + (void) puts("\nJU_DELETEINPLACE():"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, WSIZE, (uint8_t *) eleaf); + JU_DELETEINPLACE(eleaf, INDEXES, ioffset); + PrintLeaf("After ", ioffset, WSIZE, (uint8_t *) eleaf); + } + + (void) puts("\nJU_DELETEINPLACE_ODD(3):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 3, oleaf3); + JU_DELETEINPLACE_ODD(oleaf3, INDEXES, ioffset, 3); + PrintLeaf("After ", ioffset, 3, oleaf3); + } + +#ifdef JU_64BIT + (void) puts("\nJU_DELETEINPLACE_ODD(5):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 5, oleaf5); + JU_DELETEINPLACE_ODD(oleaf5, INDEXES, ioffset, 5); + PrintLeaf("After ", ioffset, 5, oleaf5); + } + + (void) puts("\nJU_DELETEINPLACE_ODD(6):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 6, oleaf6); + JU_DELETEINPLACE_ODD(oleaf6, INDEXES, ioffset, 6); + PrintLeaf("After ", ioffset, 6, oleaf6); + } + + (void) puts("\nJU_DELETEINPLACE_ODD(7):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT; + PRINTLEAF("Before", ioffset, 7, oleaf7); + JU_DELETEINPLACE_ODD(oleaf7, INDEXES, ioffset, 7); + PrintLeaf("After ", ioffset, 7, oleaf7); + } +#endif // JU_64BIT + + (void) puts("\nJU_INSERTCOPY():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, WSIZE, (uint8_t *) eleaf); + PRINTLEAF("Before, dest", ioffset, WSIZE, (uint8_t *) eleaf_2); + JU_INSERTCOPY(eleaf_2, eleaf, INDEXES, ioffset, eIndex); + PRINTLEAF("After, src ", ioffset, WSIZE, (uint8_t *) eleaf); + PrintLeaf("After, dest", ioffset, WSIZE, (uint8_t *) eleaf_2); + } + + (void) puts("\nJU_INSERTCOPY3():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 3, oleaf3); + PRINTLEAF("Before, dest", ioffset, 3, oleaf3_2); + JU_INSERTCOPY3(oleaf3_2, oleaf3, INDEXES, ioffset, oIndex); + PRINTLEAF("After, src ", ioffset, 3, oleaf3); + PrintLeaf("After, dest", ioffset, 3, oleaf3_2); + } + +#ifdef JU_64BIT + (void) puts("\nJU_INSERTCOPY5():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 5, oleaf5); + PRINTLEAF("Before, dest", ioffset, 5, oleaf5_2); + JU_INSERTCOPY5(oleaf5_2, oleaf5, INDEXES, ioffset, oIndex); + PRINTLEAF("After, src ", ioffset, 5, oleaf5); + PrintLeaf("After, dest", ioffset, 5, oleaf5_2); + } + + (void) puts("\nJU_INSERTCOPY6():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 6, oleaf6); + PRINTLEAF("Before, dest", ioffset, 6, oleaf6_2); + JU_INSERTCOPY6(oleaf6_2, oleaf6, INDEXES, ioffset, oIndex); + PRINTLEAF("After, src ", ioffset, 6, oleaf6); + PrintLeaf("After, dest", ioffset, 6, oleaf6_2); + } + + (void) puts("\nJU_INSERTCOPY7():"); + + for (ioffset = 0; ioffset <= INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 7, oleaf7); + PRINTLEAF("Before, dest", ioffset, 7, oleaf7_2); + JU_INSERTCOPY7(oleaf7_2, oleaf7, INDEXES, ioffset, oIndex); + PRINTLEAF("After, src ", ioffset, 7, oleaf7); + PrintLeaf("After, dest", ioffset, 7, oleaf7_2); + } +#endif // JU_64BIT + + (void) puts("\nJU_DELETECOPY():"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, WSIZE, (uint8_t *) eleaf); + PRINTLEAF("Before, dest", ioffset, WSIZE, (uint8_t *) eleaf_2); + JU_DELETECOPY(eleaf_2, eleaf, INDEXES, ioffset, ignore); + PRINTLEAF("After, src ", ioffset, WSIZE, (uint8_t *) eleaf); + PrintLeaf("After, dest", ioffset, WSIZE, (uint8_t *) eleaf_2); + } + + (void) puts("\nJU_DELETECOPY_ODD(3):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 3, oleaf3); + PRINTLEAF("Before, dest", ioffset, 3, oleaf3_2); + JU_DELETECOPY_ODD(oleaf3_2, oleaf3, INDEXES, ioffset, 3); + PRINTLEAF("After, src ", ioffset, 3, oleaf3); + PrintLeaf("After, dest", ioffset, 3, oleaf3_2); + } + +#ifdef JU_64BIT + (void) puts("\nJU_DELETECOPY_ODD(5):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 5, oleaf5); + PRINTLEAF("Before, dest", ioffset, 5, oleaf5_2); + JU_DELETECOPY_ODD(oleaf5_2, oleaf5, INDEXES, ioffset, 5); + PRINTLEAF("After, src ", ioffset, 5, oleaf5); + PrintLeaf("After, dest", ioffset, 5, oleaf5_2); + } + + (void) puts("\nJU_DELETECOPY_ODD(6):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 6, oleaf6); + PRINTLEAF("Before, dest", ioffset, 6, oleaf6_2); + JU_DELETECOPY_ODD(oleaf6_2, oleaf6, INDEXES, ioffset, 6); + PRINTLEAF("After, src ", ioffset, 6, oleaf6); + PrintLeaf("After, dest", ioffset, 6, oleaf6_2); + } + + (void) puts("\nJU_DELETECOPY_ODD(7):"); + + for (ioffset = 0; ioffset < INDEXES; ++ioffset) + { + INIT2; + PRINTLEAF("Before, src ", ioffset, 7, oleaf7); + PRINTLEAF("Before, dest", ioffset, 7, oleaf7_2); + JU_DELETECOPY_ODD(oleaf7_2, oleaf7, INDEXES, ioffset, 7); + PRINTLEAF("After, src ", ioffset, 7, oleaf7); + PrintLeaf("After, dest", ioffset, 7, oleaf7_2); + } +#endif // JU_64BIT + + return(0); + +} // main() + +#endif // TEST_INSDEL |