448 lines
16 KiB
C
448 lines
16 KiB
C
/***--
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** lflashimg.c
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** Dump a compiled Proto hiearchy to a RO (FLash) image file
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** See Copyright Notice in lua.h
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*/
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#define LUAC_CROSS_FILE
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#include <ctype.h>
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#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#define lflashimg_c
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#define LUA_CORE
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#include "lobject.h"
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#include "lstring.h"
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#include "lflash.h"
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#include "uzlib.h"
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//#define LOCAL_DEBUG
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#if INT_MAX != 2147483647
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# error "luac.cross requires C toolchain with 4 byte word size"
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#endif
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#define WORDSIZE ((int) sizeof(int))
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#define ALIGN(s) (((s)+(WORDSIZE-1)) & (-(signed) WORDSIZE))
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#define WORDSHIFT 2
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typedef unsigned int uint;
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#define FLASH_WORDS(t) (sizeof(t)/sizeof(FlashAddr))
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/*
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*
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* This dumper is a variant of the standard ldump, in that instead of producing a
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* binary loader format that lundump can load, it produces an image file that can be
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* directly mapped or copied into addressable memory. The typical application is on
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* small memory IoT devices which support programmable flash storage such as the
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* ESP8266. A 64 Kb LFS image has 16Kb words and will enable all program-related
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* storage to be accessed directly from flash, leaving the RAM for true R/W
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* application data.
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*
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* The start address of the Lua Flash Store (LFS) is build-dependent, and the cross
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* compiler '-a' option allows the developer to fix the LFS at a defined flash memory
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* address. Alternatively and by default the cross compilation adopts a position
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* independent image format, which permits the on-device image loader to load the LFS
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* image at an appropriate base within the flash address space. As all objects in the
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* LFS can be treated as multiples of 4-byte words, also all address fields are both
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* word aligned, and any address references within the LFS are also word-aligned.
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*
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* This version adds gzip compression of the generated LFS image for more efficient
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* over-the-air (OTA) transfer, so the method of tagging address words has been
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* replaced by a scheme which achieves better compression: an additional bitmap
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* has been added to the image, with each bit corresponding to a word in the image
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* and set if the corresponding work is an address. The addresses are stored as
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* signed relative word offsets.
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*
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* The unloader is documented in lflash.c Note that his relocation process is
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* skipped for absolute addressed images (which are identified by the
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* FLASH_SIG_ABSOLUTE bit setting in the flash signature).
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*
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* The flash image has a standard header detailed in lflash.h
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*
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* Note that luac.cross may be compiled on any little-endian machine with 32 or 64 bit
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* word length so Flash addresses can't be handled as standard C pointers as size_t
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* and int may not have the same size. Hence addresses with the must be declared as
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* the FlashAddr type rather than typed C pointers and must be accessed through macros.
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*
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* Also note that image built with a given LUA_PACK_TVALUES / LUA_NUNBER_INTEGRAL
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* combination must be loaded into a corresponding firmware build. Hence these
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* configuration options are also included in the FLash Signature.
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*
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* The Flash image is assembled up by first building the RO stringtable containing
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* all strings used in the compiled proto hierarchy. This is followed by the Protos.
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*
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* The storage is allocated bottom up using a serial allocator and the algortihm for
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* building the image essentially does a bottom-uo serial enumeration so that any
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* referenced storage has already been allocated in the image, and therefore (with the
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* exception of the Flash Header) all pointer references are backwards.
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*
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* As addresses are 4 byte on the target and either 4 or (typically) 8 bytes on the
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* host so any structures containing address fields (TStrings, TValues, Protos, other
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* address vectors) need repacking.
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*/
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typedef struct flashts { /* This is the fixed 32-bit equivalent of TString */
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FlashAddr next;
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lu_byte tt;
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lu_byte marked;
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int hash;
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int len;
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} FlashTS;
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#ifndef LUA_MAX_FLASH_SIZE
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#define LUA_MAX_FLASH_SIZE 0x10000 //in words
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#endif
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static uint curOffset = 0;
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/*
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* The flashAddrTag is a bit array, one bit per flashImage word denoting
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* whether the corresponding word is a relative address. The defines
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* are access methods for this bit array.
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*/
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static uint flashImage[LUA_MAX_FLASH_SIZE + LUA_MAX_FLASH_SIZE/32];
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static uint *flashAddrTag = flashImage + LUA_MAX_FLASH_SIZE;
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#define _TW(v) (v)>>5
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#define _TB(v) (1<<((v)&0x1F))
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#define setFlashAddrTag(v) flashAddrTag[_TW(v)] |= _TB(v)
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#define getFlashAddrTag(v) ((flashAddrTag[_TW(v)]&_TB(v)) != 0)
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#define fatal luac_fatal
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#ifdef _MSC_VER
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extern void __declspec( noreturn ) luac_fatal( const char* message );
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#else
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extern void __attribute__((noreturn)) luac_fatal(const char* message);
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#endif
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#ifdef LOCAL_DEBUG
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#define DBG_PRINT(...) printf(__VA_ARGS__)
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#else
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#define DBG_PRINT(...) ((void)0)
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#endif
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/*
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* Serial allocator. Throw a luac-style out of memory error is allocaiton fails.
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*/
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static void *flashAlloc(lua_State* L, size_t n) {
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void *p = (void *)(flashImage + curOffset);
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curOffset += ALIGN(n)>>WORDSHIFT;
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if (curOffset > LUA_MAX_FLASH_SIZE) {
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fatal("Out of Flash memory");
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}
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return p;
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}
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/*
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* Convert an absolute address pointing inside the flash image to offset form.
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* This macro form also takes the lvalue destination so that this can be tagged
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* as a relocatable address.
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*/
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#define toFlashAddr(l, pd, s) _toFlashAddr(l, &(pd), s)
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static void _toFlashAddr(lua_State* L, FlashAddr *a, void *p) {
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uint doffset = cast(char *, a) - cast(char *,flashImage);
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lua_assert(!(doffset & (WORDSIZE-1))); // check word aligned
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doffset >>= WORDSHIFT; // and convert to a word offset
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lua_assert(doffset <= curOffset);
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if (p) {
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uint poffset = cast(char *, p) - cast(char *,flashImage);
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lua_assert(!(poffset & (WORDSIZE-1)));
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poffset >>= WORDSHIFT;
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lua_assert(poffset <= curOffset);
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flashImage[doffset] = poffset; // Set the pointer to the offset
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setFlashAddrTag(doffset); // And tag as an address
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} /* else leave clear */ // Special case for NULL pointer
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}
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/*
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* Convert an image address in offset form back to (host) absolute form
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*/
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static void *fromFashAddr(FlashAddr a) {
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return a ? cast(void *, flashImage + a) : NULL;
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}
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/*
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* Add a TS found in the Proto Load to the table at the ToS
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*/
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static void addTS(lua_State *L, TString *ts) {
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lua_assert(ts->tsv.tt==LUA_TSTRING);
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lua_pushnil(L);
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setsvalue(L, L->top-1, ts);
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lua_pushinteger(L, 1);
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lua_rawset(L, -3);
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DBG_PRINT("Adding string: %s\n",getstr(ts));
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}
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/*
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* Enumerate all of the Protos in the Proto hiearchy and scan contents to collect
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* all referenced strings in a Lua Array at ToS.
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*/
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static void scanProtoStrings(lua_State *L, const Proto* f) {
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/* Table at L->Top[-1] is used to collect the strings */
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int i;
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if (f->source)
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addTS(L, f->source);
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#ifdef LUA_OPTIMIZE_DEBUG
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if (f->packedlineinfo)
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addTS(L, luaS_new(L, cast(const char *, f->packedlineinfo)));
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#endif
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for (i = 0; i < f->sizek; i++) {
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if (ttisstring(f->k + i))
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addTS(L, rawtsvalue(f->k + i));
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}
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for (i = 0; i < f->sizeupvalues; i++) addTS(L, f->upvalues[i]);
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for (i = 0; i < f->sizelocvars; i++) addTS(L, f->locvars[i].varname);
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for (i = 0; i < f->sizep; i++) scanProtoStrings(L, f->p[i]);
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}
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/*
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* Use the collected strings table to build the new ROstrt in the Flash Image
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*
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* The input is an array of {"SomeString" = 1, ...} on the ToS.
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* The output is an array of {"SomeString" = FlashOffset("SomeString"), ...} on ToS
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*/
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static void createROstrt(lua_State *L, FlashHeader *fh) {
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/* Table at L->Top[-1] on input is hash used to collect the strings */
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/* Count the number of strings. Can't use objlen as this is a hash */
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fh->nROuse = 0;
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lua_pushnil(L); /* first key */
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while (lua_next(L, -2) != 0) {
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fh->nROuse++;
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DBG_PRINT("Found: %s\n",getstr(rawtsvalue(L->top-2)));
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lua_pop(L, 1); // dump the value
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}
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fh->nROsize = 2<<luaO_log2(fh->nROuse);
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FlashAddr *hashTab = flashAlloc(L, fh->nROsize * WORDSIZE);
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toFlashAddr(L, fh->pROhash, hashTab);
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/* Now iterate over the strings to be added to the RO string table and build it */
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lua_newtable(L); // add output table
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lua_pushnil(L); // First key
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while (lua_next(L, -3) != 0) { // replaces key, pushes value
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TString *ts = rawtsvalue(L->top - 2); // key.ts
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const char *p = getstr(ts); // C string of key
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uint hash = ts->tsv.hash; // hash of key
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size_t len = ts->tsv.len; // and length
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DBG_PRINT("2nd pass: %s\n",p);
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FlashAddr *e = hashTab + lmod(hash, fh->nROsize);
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FlashTS *last = cast(FlashTS *, fromFashAddr(*e));
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FlashTS *fts = cast(FlashTS *, flashAlloc(L, sizeof(FlashTS)));
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toFlashAddr(L, *e, fts); // add reference to TS to lookup vector
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toFlashAddr(L, fts->next, last); // and chain to previous entry if any
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fts->tt = LUA_TSTRING; // Set as String
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fts->marked = bitmask(LFSBIT); // LFS string with no Whitebits set
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fts->hash = hash; // add hash
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fts->len = len; // and length
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memcpy(flashAlloc(L, len+1), p, len+1); // copy string
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// include the trailing null char
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lua_pop(L, 1); // Junk the value
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lua_pushvalue(L, -1); // Dup the key as rawset dumps its copy
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lua_pushinteger(L, cast(FlashAddr*,fts)-flashImage); // Value is new TS offset.
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lua_rawset(L, -4); // Add to new table
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}
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/* At this point the old hash is done to derefence for GC */
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lua_remove(L, -2);
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}
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/*
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* Convert a TString reference in the host G(L)->strt entry into the corresponding
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* TString address in the flashImage using the lookup table at ToS
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*/
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static void *resolveTString(lua_State* L, TString *s) {
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if (!s)
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return NULL;
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lua_pushnil(L);
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setsvalue(L, L->top-1, s);
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lua_rawget(L, -2);
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lua_assert(!lua_isnil(L, -1));
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void *ts = fromFashAddr(lua_tointeger(L, -1));
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lua_pop(L, 1);
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return ts;
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}
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/*
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* In order to simplify repacking of structures from the host format to that target
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* format, this simple copy routine is data-driven by a simple format specifier.
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* n Number of consecutive records to be processed
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* fmt A string of A, I, S, V specifiers spanning the record.
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* src Source of record
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* returns Address of destination record
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*/
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#if defined(LUA_PACK_TVALUES)
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#define TARGET_TV_SIZE (sizeof(lua_Number)+sizeof(lu_int32))
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#else
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#define TARGET_TV_SIZE (2*sizeof(lua_Number))
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#endif
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static void *flashCopy(lua_State* L, int n, const char *fmt, void *src) {
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/* ToS is the string address mapping table */
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if (n == 0)
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return NULL;
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int i, recsize;
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void *newts;
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/* A bit of a botch because fmt is either "V" or a string of WORDSIZE specifiers */
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/* The size 8 / 12 / 16 bytes for integer builds, packed TV and default TVs resp */
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if (fmt[0]=='V') {
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lua_assert(fmt[1] == 0); /* V formats must be singetons */
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recsize = TARGET_TV_SIZE;
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} else {
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recsize = WORDSIZE * strlen(fmt);
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}
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uint *d = cast(uint *, flashAlloc(L, n * recsize));
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uint *dest = d;
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uint *s = cast(uint *, src);
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for (i = 0; i < n; i++) {
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const char *p = fmt;
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while (*p) {
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/* All input address types (A,S,V) are aligned to size_t boundaries */
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if (*p != 'I' && ((size_t)s)&(sizeof(size_t)-1))
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s++;
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switch (*p++) {
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case 'A':
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toFlashAddr(L, *d, *cast(void**, s));
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s += FLASH_WORDS(size_t);
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d++;
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break;
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case 'I':
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*d++ = *s++;
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break;
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case 'H':
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*d++ = (*s++) & 0;
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break;
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case 'S':
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newts = resolveTString(L, *cast(TString **, s));
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toFlashAddr(L, *d, newts);
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s += FLASH_WORDS(size_t);
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d++;
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break;
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case 'V':
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/* This code has to work for both Integer and Float build variants */
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memset(d, 0, TARGET_TV_SIZE);
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TValue *sv = cast(TValue *, s);
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/* The value is 0, 4 or 8 bytes depending on type */
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if (ttisstring(sv)) {
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toFlashAddr(L, *d, resolveTString(L, rawtsvalue(sv)));
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} else if (ttisnumber(sv)) {
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*cast(lua_Number*,d) = *cast(lua_Number*,s);
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} else if (!ttisnil(sv)){
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/* all other types are 4 byte */
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lua_assert(!iscollectable(sv));
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*cast(uint *,d) = *cast(uint *,s);
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}
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*cast(int *,cast(lua_Number*,d)+1) = ttype(sv);
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s += FLASH_WORDS(TValue);
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d += TARGET_TV_SIZE/WORDSIZE;
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break;
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default:
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lua_assert (0);
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}
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}
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}
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return dest;
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}
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/* The debug optimised version has a different Proto layout */
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#ifdef LUA_OPTIMIZE_DEBUG
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#define PROTO_COPY_MASK "AHAAAAAASIIIIIIIAI"
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#else
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#define PROTO_COPY_MASK "AHAAAAAASIIIIIIIIAI"
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#endif
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/*
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* Do the actual prototype copy.
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*/
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static void *functionToFlash(lua_State* L, const Proto* orig) {
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Proto f;
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int i;
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memcpy (&f, orig, sizeof(Proto));
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f.gclist = NULL;
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f.next = NULL;
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l_setbit(f.marked, LFSBIT); /* OK to set the LFSBIT on a stack-cloned copy */
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if (f.sizep) { /* clone included Protos */
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Proto **p = luaM_newvector(L, f.sizep, Proto *);
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for (i=0; i<f.sizep; i++)
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p[i] = cast(Proto *, functionToFlash(L, f.p[i]));
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f.p = cast(Proto **, flashCopy(L, f.sizep, "A", p));
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luaM_freearray(L, p, f.sizep, Proto *);
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}
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f.k = cast(TValue *, flashCopy(L, f.sizek, "V", f.k));
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f.code = cast(Instruction *, flashCopy(L, f.sizecode, "I", f.code));
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#ifdef LUA_OPTIMIZE_DEBUG
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if (f.packedlineinfo) {
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TString *ts=luaS_new(L, cast(const char *,f.packedlineinfo));
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f.packedlineinfo = cast(unsigned char *, resolveTString(L, ts)) + sizeof (FlashTS);
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}
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#else
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f.lineinfo = cast(int *, flashCopy(L, f.sizelineinfo, "I", f.lineinfo));
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#endif
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f.locvars = cast(struct LocVar *, flashCopy(L, f.sizelocvars, "SII", f.locvars));
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f.upvalues = cast(TString **, flashCopy(L, f.sizeupvalues, "S", f.upvalues));
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return cast(void *, flashCopy(L, 1, PROTO_COPY_MASK, &f));
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}
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uint dumpToFlashImage (lua_State* L, const Proto *main, lua_Writer w,
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void* data, int strip,
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lu_int32 address, lu_int32 maxSize) {
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// parameter strip is ignored for now
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FlashHeader *fh = cast(FlashHeader *, flashAlloc(L, sizeof(FlashHeader)));
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int i, status;
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lua_newtable(L);
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scanProtoStrings(L, main);
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createROstrt(L, fh);
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toFlashAddr(L, fh->mainProto, functionToFlash(L, main));
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fh->flash_sig = FLASH_SIG + (address ? FLASH_SIG_ABSOLUTE : 0);
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fh->flash_size = curOffset*WORDSIZE;
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if (fh->flash_size>maxSize) {
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fatal ("The image is too large for specfied LFS size");
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}
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if (address) { /* in absolute mode convert addresses to mapped address */
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for (i = 0 ; i < curOffset; i++)
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if (getFlashAddrTag(i))
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flashImage[i] = 4*flashImage[i] + address;
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lua_unlock(L);
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status = w(L, flashImage, fh->flash_size, data);
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} else { /* compressed PI mode */
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/*
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* In image mode, shift the relocation bitmap down directly above
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* the used flashimage. This consolidated array is then gzipped.
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*/
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uint oLen;
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uint8_t *oBuf;
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int bmLen = sizeof(uint)*((curOffset+31)/32); /* 32 flags to a word */
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memmove(flashImage+curOffset, flashAddrTag, bmLen);
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status = uzlib_compress (&oBuf, &oLen,
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(const uint8_t *)flashImage, bmLen+fh->flash_size);
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if (status != UZLIB_OK) {
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luac_fatal("Out of memory during image compression");
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}
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lua_unlock(L);
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#if 0
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status = w(L, flashImage, bmLen+fh->flash_size, data);
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#else
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status = w(L, oBuf, oLen, data);
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free(oBuf);
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#endif
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}
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lua_lock(L);
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return status;
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}
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