Mercurial > projects > ldc
view runtime/internal/aaA.d @ 834:f466f475b654
Added proper "need 'this' to access member foo" errors instead of "variable foo not resolved" for some cases, added FIXME for the old error!
Added a bit more information to the runtime's cyclic dependency detection exception.
| author | Tomas Lindquist Olsen <tomas.l.olsen@gmail.com> |
|---|---|
| date | Tue, 09 Dec 2008 01:56:39 +0100 |
| parents | a26b0c5d5942 |
| children | f5f8c21ce6ef |
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//_ aaA.d /** * Part of the D programming language runtime library. * Implementation of associative arrays. */ /* * Copyright (C) 2000-2008 by Digital Mars, www.digitalmars.com * Written by Walter Bright * * This software is provided 'as-is', without any express or implied * warranty. In no event will the authors be held liable for any damages * arising from the use of this software. * * Permission is granted to anyone to use this software for any purpose, * including commercial applications, and to alter it and redistribute it * freely, subject to the following restrictions: * * o The origin of this software must not be misrepresented; you must not * claim that you wrote the original software. If you use this software * in a product, an acknowledgment in the product documentation would be * appreciated but is not required. * o Altered source versions must be plainly marked as such, and must not * be misrepresented as being the original software. * o This notice may not be removed or altered from any source * distribution. */ /* * Modified by Sean Kelly <sean@f4.ca> for use with Tango. * Modified by Tomas Lindquist Olsen <tomas@famolsen.dk> for use with LDC. */ private { import tango.stdc.stdarg; import tango.stdc.string; enum BlkAttr : uint { FINALIZE = 0b0000_0001, NO_SCAN = 0b0000_0010, NO_MOVE = 0b0000_0100, ALL_BITS = 0b1111_1111 } extern (C) void* gc_malloc( size_t sz, uint ba = 0 ); extern (C) void* gc_calloc( size_t sz, uint ba = 0 ); extern (C) void gc_free( void* p ); } // Auto-rehash and pre-allocate - Dave Fladebo static size_t[] prime_list = [ 97UL, 389UL, 1_543UL, 6_151UL, 24_593UL, 98_317UL, 393_241UL, 1_572_869UL, 6_291_469UL, 25_165_843UL, 100_663_319UL, 402_653_189UL, 1_610_612_741UL, 4_294_967_291UL, // 8_589_934_513UL, 17_179_869_143UL ]; struct aaA { aaA *left; aaA *right; hash_t hash; /* key */ /* value */ } struct BB { aaA*[] b; size_t nodes; // total number of aaA nodes TypeInfo keyti; // TODO: replace this with TypeInfo_AssociativeArray when available in _aaGet() } /* This is the type actually seen by the programmer, although * it is completely opaque. */ // LDC doesn't pass structs in registers so no need to wrap it ... alias BB* AA; /********************************** * Align to next pointer boundary, so that * GC won't be faced with misaligned pointers * in value. */ size_t aligntsize(size_t tsize) { return (tsize + size_t.sizeof - 1) & ~(size_t.sizeof - 1); } extern (C): /************************************************* * Invariant for aa. */ /+ void _aaInvAh(aaA*[] aa) { for (size_t i = 0; i < aa.length; i++) { if (aa[i]) _aaInvAh_x(aa[i]); } } private int _aaCmpAh_x(aaA *e1, aaA *e2) { int c; c = e1.hash - e2.hash; if (c == 0) { c = e1.key.length - e2.key.length; if (c == 0) c = memcmp((char *)e1.key, (char *)e2.key, e1.key.length); } return c; } private void _aaInvAh_x(aaA *e) { hash_t key_hash; aaA *e1; aaA *e2; key_hash = getHash(e.key); assert(key_hash == e.hash); while (1) { int c; e1 = e.left; if (e1) { _aaInvAh_x(e1); // ordinary recursion do { c = _aaCmpAh_x(e1, e); assert(c < 0); e1 = e1.right; } while (e1 != null); } e2 = e.right; if (e2) { do { c = _aaCmpAh_x(e, e2); assert(c < 0); e2 = e2.left; } while (e2 != null); e = e.right; // tail recursion } else break; } } +/ /**************************************************** * Determine number of entries in associative array. */ size_t _aaLen(AA aa) in { //printf("_aaLen()+\n"); //_aaInv(aa); } out (result) { size_t len = 0; void _aaLen_x(aaA* ex) { auto e = ex; len++; while (1) { if (e.right) _aaLen_x(e.right); e = e.left; if (!e) break; len++; } } if (aa) { foreach (e; aa.b) { if (e) _aaLen_x(e); } } assert(len == result); //printf("_aaLen()-\n"); } body { return aa ? aa.nodes : 0; } /************************************************* * Get pointer to value in associative array indexed by key. * Add entry for key if it is not already there. */ void* _aaGet(AA* aa_arg, TypeInfo keyti, size_t valuesize, void* pkey) in { assert(aa_arg); } out (result) { assert(result); assert(*aa_arg); assert((*aa_arg).b.length); //assert(_aaInAh(*aa, key)); } body { //auto pkey = cast(void *)(&valuesize + 1); size_t i; aaA *e; auto keysize = aligntsize(keyti.tsize()); if (!*aa_arg) *aa_arg = new BB(); auto aa = *aa_arg; aa.keyti = keyti; if (!aa.b.length) { alias aaA *pa; auto len = prime_list[0]; aa.b = new pa[len]; } auto key_hash = keyti.getHash(pkey); //printf("hash = %d\n", key_hash); i = key_hash % aa.b.length; auto pe = &aa.b[i]; while ((e = *pe) !is null) { if (key_hash == e.hash) { auto c = keyti.compare(pkey, e + 1); if (c == 0) goto Lret; pe = (c < 0) ? &e.left : &e.right; } else pe = (key_hash < e.hash) ? &e.left : &e.right; } // Not found, create new elem //printf("create new one\n"); size_t size = aaA.sizeof + keysize + valuesize; e = cast(aaA *) gc_calloc(size); memcpy(e + 1, pkey, keysize); e.hash = key_hash; *pe = e; auto nodes = ++aa.nodes; //printf("length = %d, nodes = %d\n", (*aa).length, nodes); if (nodes > aa.b.length * 4) { _aaRehash(aa_arg,keyti); } Lret: return cast(void *)(e + 1) + keysize; } /************************************************* * Get pointer to value in associative array indexed by key. * Returns null if it is not already there. */ void* _aaGetRvalue(AA aa, TypeInfo keyti, size_t valuesize, void *pkey) { //printf("_aaGetRvalue(valuesize = %u)\n", valuesize); if (!aa) return null; //auto pkey = cast(void *)(&valuesize + 1); auto keysize = aligntsize(keyti.tsize()); auto len = aa.b.length; if (len) { auto key_hash = keyti.getHash(pkey); //printf("hash = %d\n", key_hash); size_t i = key_hash % len; auto e = aa.b[i]; while (e !is null) { if (key_hash == e.hash) { auto c = keyti.compare(pkey, e + 1); if (c == 0) return cast(void *)(e + 1) + keysize; e = (c < 0) ? e.left : e.right; } else e = (key_hash < e.hash) ? e.left : e.right; } } return null; // not found, caller will throw exception } /************************************************* * Determine if key is in aa. * Returns: * null not in aa * !=null in aa, return pointer to value */ void* _aaIn(AA aa, TypeInfo keyti, void *pkey) in { } out (result) { //assert(result == 0 || result == 1); } body { if (aa) { //auto pkey = cast(void *)(&keyti + 1); //printf("_aaIn(), .length = %d, .ptr = %x\n", aa.length, cast(uint)aa.ptr); auto len = aa.b.length; if (len) { auto key_hash = keyti.getHash(pkey); //printf("hash = %d\n", key_hash); size_t i = key_hash % len; auto e = aa.b[i]; while (e !is null) { if (key_hash == e.hash) { auto c = keyti.compare(pkey, e + 1); if (c == 0) return cast(void *)(e + 1) + aligntsize(keyti.tsize()); e = (c < 0) ? e.left : e.right; } else e = (key_hash < e.hash) ? e.left : e.right; } } } // Not found return null; } /************************************************* * Delete key entry in aa[]. * If key is not in aa[], do nothing. */ void _aaDel(AA aa, TypeInfo keyti, void *pkey) { //auto pkey = cast(void *)(&keyti + 1); aaA *e; if (aa && aa.b.length) { auto key_hash = keyti.getHash(pkey); //printf("hash = %d\n", key_hash); size_t i = key_hash % aa.b.length; auto pe = &aa.b[i]; while ((e = *pe) !is null) // null means not found { if (key_hash == e.hash) { auto c = keyti.compare(pkey, e + 1); if (c == 0) { if (!e.left && !e.right) { *pe = null; } else if (e.left && !e.right) { *pe = e.left; e.left = null; } else if (!e.left && e.right) { *pe = e.right; e.right = null; } else { *pe = e.left; e.left = null; do pe = &(*pe).right; while (*pe); *pe = e.right; e.right = null; } aa.nodes--; gc_free(e); break; } pe = (c < 0) ? &e.left : &e.right; } else pe = (key_hash < e.hash) ? &e.left : &e.right; } } } /******************************************** * Produce array of values from aa. * The actual type is painted on the return value by the frontend * This means the returned length should be the number of elements */ void[] _aaValues(AA aa, size_t keysize, size_t valuesize) in { assert(keysize == aligntsize(keysize)); } body { size_t resi; void[] a; void _aaValues_x(aaA* e) { do { memcpy(a.ptr + resi * valuesize, cast(byte*)e + aaA.sizeof + keysize, valuesize); resi++; if (e.left) { if (!e.right) { e = e.left; continue; } _aaValues_x(e.left); } e = e.right; } while (e !is null); } if (aa) { auto len = _aaLen(aa); auto ptr = cast(byte*) gc_malloc(len * valuesize, valuesize < (void*).sizeof ? BlkAttr.NO_SCAN : 0); a = ptr[0 .. len]; resi = 0; foreach (e; aa.b) { if (e) _aaValues_x(e); } assert(resi == a.length); } return a; } /******************************************** * Rehash an array. */ void* _aaRehash(AA* paa, TypeInfo keyti) in { //_aaInvAh(paa); } out (result) { //_aaInvAh(result); } body { BB newb; void _aaRehash_x(aaA* olde) { while (1) { auto left = olde.left; auto right = olde.right; olde.left = null; olde.right = null; aaA *e; //printf("rehash %p\n", olde); auto key_hash = olde.hash; size_t i = key_hash % newb.b.length; auto pe = &newb.b[i]; while ((e = *pe) !is null) { //printf("\te = %p, e.left = %p, e.right = %p\n", e, e.left, e.right); assert(e.left != e); assert(e.right != e); if (key_hash == e.hash) { auto c = keyti.compare(olde + 1, e + 1); assert(c != 0); pe = (c < 0) ? &e.left : &e.right; } else pe = (key_hash < e.hash) ? &e.left : &e.right; } *pe = olde; if (right) { if (!left) { olde = right; continue; } _aaRehash_x(right); } if (!left) break; olde = left; } } //printf("Rehash\n"); if (*paa) { auto aa = *paa; auto len = _aaLen(aa); if (len) { size_t i; for (i = 0; i < prime_list.length - 1; i++) { if (len <= prime_list[i]) break; } len = prime_list[i]; newb.b = new aaA*[len]; newb.keyti = keyti; foreach (e; aa.b) { if (e) _aaRehash_x(e); } newb.nodes = (*aa).nodes; } **paa = newb; } return *paa; } /******************************************** * Produce array of N byte keys from aa. * The actual type is painted on the return value by the frontend * This means the returned length should be the number of elements */ void[] _aaKeys(AA aa, size_t keysize) { byte[] res; size_t resi; void _aaKeys_x(aaA* e) { do { memcpy(&res[resi * keysize], cast(byte*)(e + 1), keysize); resi++; if (e.left) { if (!e.right) { e = e.left; continue; } _aaKeys_x(e.left); } e = e.right; } while (e !is null); } auto len = _aaLen(aa); if (!len) return null; res = (cast(byte*) gc_malloc(len * keysize, !(aa.keyti.flags() & 1) ? BlkAttr.NO_SCAN : 0)) [0 .. len * keysize]; resi = 0; foreach (e; aa.b) { if (e) _aaKeys_x(e); } assert(resi == len); return res.ptr[0 .. len]; } /********************************************** * 'apply' for associative arrays - to support foreach */ // dg is D, but _aaApply() is C extern (D) typedef int delegate(void *) dg_t; int _aaApply(AA aa, size_t keysize, dg_t dg) in { assert(aligntsize(keysize) == keysize); } body { int result; //printf("_aaApply(aa = x%llx, keysize = %d, dg = x%llx)\n", aa, keysize, dg); int treewalker(aaA* e) { int result; do { //printf("treewalker(e = %p, dg = x%llx)\n", e, dg); result = dg(cast(void *)(e + 1) + keysize); if (result) break; if (e.right) { if (!e.left) { e = e.right; continue; } result = treewalker(e.right); if (result) break; } e = e.left; } while (e); return result; } if (aa) { foreach (e; aa.b) { if (e) { result = treewalker(e); if (result) break; } } } return result; } // dg is D, but _aaApply2() is C extern (D) typedef int delegate(void *, void *) dg2_t; int _aaApply2(AA aa, size_t keysize, dg2_t dg) in { assert(aligntsize(keysize) == keysize); } body { int result; //printf("_aaApply(aa = x%llx, keysize = %d, dg = x%llx)\n", aa, keysize, dg); int treewalker(aaA* e) { int result; do { //printf("treewalker(e = %p, dg = x%llx)\n", e, dg); result = dg(cast(void *)(e + 1), cast(void *)(e + 1) + keysize); if (result) break; if (e.right) { if (!e.left) { e = e.right; continue; } result = treewalker(e.right); if (result) break; } e = e.left; } while (e); return result; } if (aa) { foreach (e; aa.b) { if (e) { result = treewalker(e); if (result) break; } } } return result; } /*********************************** * Construct an associative array of type ti from * length pairs of key/value pairs. */ /+ extern (C) BB* _d_assocarrayliteralT(TypeInfo_AssociativeArray ti, size_t length, ...) { auto valuesize = ti.next.tsize(); // value size auto keyti = ti.key; auto keysize = keyti.tsize(); // key size BB* result; //printf("_d_assocarrayliteralT(keysize = %d, valuesize = %d, length = %d)\n", keysize, valuesize, length); //printf("tivalue = %.*s\n", ti.next.classinfo.name); if (length == 0 || valuesize == 0 || keysize == 0) { ; } else { va_list q; va_start!(size_t)(q, length); result = new BB(); size_t i; for (i = 0; i < prime_list.length - 1; i++) { if (length <= prime_list[i]) break; } auto len = prime_list[i]; result.b = new aaA*[len]; size_t keystacksize = (keysize + int.sizeof - 1) & ~(int.sizeof - 1); size_t valuestacksize = (valuesize + int.sizeof - 1) & ~(int.sizeof - 1); size_t keytsize = aligntsize(keysize); for (size_t j = 0; j < length; j++) { void* pkey = q; q += keystacksize; void* pvalue = q; q += valuestacksize; aaA* e; auto key_hash = keyti.getHash(pkey); //printf("hash = %d\n", key_hash); i = key_hash % len; auto pe = &result.b[i]; while (1) { e = *pe; if (!e) { // Not found, create new elem //printf("create new one\n"); e = cast(aaA *) cast(void*) new void[aaA.sizeof + keytsize + valuesize]; memcpy(e + 1, pkey, keysize); e.hash = key_hash; *pe = e; result.nodes++; break; } if (key_hash == e.hash) { auto c = keyti.compare(pkey, e + 1); if (c == 0) break; pe = (c < 0) ? &e.left : &e.right; } else pe = (key_hash < e.hash) ? &e.left : &e.right; } memcpy(cast(void *)(e + 1) + keytsize, pvalue, valuesize); } va_end(q); } return result; } +/