Michael Wei
see http://mbed.org/users/no2chem/notebook/mbed-clock-control--benchmarks/
Revision 0:b5d3bd64d2dc, committed 2010-01-24
- Comitter:
- no2chem
- Date:
- Sun Jan 24 15:46:26 2010 +0000
- Commit message:
Changed in this revision
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/ClockControl/ClockControl.cpp Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,37 @@
+#include "ClockControl.h"
+
+void setPLL0Frequency(unsigned char clkSrc, unsigned short M, unsigned char N)
+{
+ LPC_SC->CLKSRCSEL = clkSrc;
+ LPC_SC->PLL0CFG = (((unsigned int)N-1) << 16) | M-1;
+ LPC_SC->PLL0CON = 0x01;
+ LPC_SC->PLL0FEED = 0xAA;
+ LPC_SC->PLL0FEED = 0x55;
+ while (!(LPC_SC->PLL0STAT & (1<<26)));
+
+ LPC_SC->PLL0CON = 0x03;
+ LPC_SC->PLL0FEED = 0xAA;
+ LPC_SC->PLL0FEED = 0x55;
+}
+
+void setPLL1Frequency(unsigned char clkSrc, unsigned short M, unsigned char N)
+{
+ LPC_SC->CLKSRCSEL = clkSrc;
+ LPC_SC->PLL1CFG = (((unsigned int)N-1) << 16) | M-1;
+ LPC_SC->PLL1CON = 0x01;
+ LPC_SC->PLL1FEED = 0xAA;
+ LPC_SC->PLL1FEED = 0x55;
+ while (!(LPC_SC->PLL1STAT & (1<<26)));
+
+ LPC_SC->PLL1CON = 0x03;
+ LPC_SC->PLL1FEED = 0xAA;
+ LPC_SC->PLL1FEED = 0x55;
+}
+
+unsigned int setSystemFrequency(unsigned char clkDivider, unsigned char clkSrc, unsigned short M, unsigned char N)
+{
+ setPLL0Frequency(clkSrc, M, N);
+ LPC_SC->CCLKCFG = clkDivider - 1;
+ SystemCoreClockUpdate();
+ return SystemCoreClock;
+}
\ No newline at end of file
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/ClockControl/ClockControl.h Sun Jan 24 15:46:26 2010 +0000 @@ -0,0 +1,14 @@ +/* mbed PowerControl Library + * Copyright (c) 2010 Michael Wei + */ + +//shouldn't have to include, but fixes weird problems with defines +#include "LPC1768/LPC17xx.h" + +#ifndef MBED_CLOCKCONTROL_H +#define MBED_CLOCKCONTROL_H + +unsigned int setSystemFrequency(unsigned char clkDivider, unsigned char clkSrc, unsigned short M, unsigned char N); +void setPLL0Frequency(unsigned char clkSrc, unsigned short M, unsigned char N); +void setPLL1Frequency(unsigned char clkSrc, unsigned short M, unsigned char N); +#endif \ No newline at end of file
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_list_join.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,496 @@
+/*
+Author : Shay Gal-On, EEMBC
+
+This file is part of EEMBC(R) and CoreMark(TM), which are Copyright (C) 2009
+All rights reserved.
+
+EEMBC CoreMark Software is a product of EEMBC and is provided under the terms of the
+CoreMark License that is distributed with the official EEMBC COREMARK Software release.
+If you received this EEMBC CoreMark Software without the accompanying CoreMark License,
+you must discontinue use and download the official release from www.coremark.org.
+
+Also, if you are publicly displaying scores generated from the EEMBC CoreMark software,
+make sure that you are in compliance with Run and Reporting rules specified in the accompanying readme.txt file.
+
+EEMBC
+4354 Town Center Blvd. Suite 114-200
+El Dorado Hills, CA, 95762
+*/
+
+#include "coremark.h"
+/*
+Topic: Description
+ Benchmark using a linked list.
+
+ Linked list is a common data structure used in many applications.
+
+ For our purposes, this will excercise the memory units of the processor.
+ In particular, usage of the list pointers to find and alter data.
+
+ We are not using Malloc since some platforms do not support this library.
+
+ Instead, the memory block being passed in is used to create a list,
+ and the benchmark takes care not to add more items then can be
+ accomodated by the memory block. The porting layer will make sure
+ that we have a valid memory block.
+
+ All operations are done in place, without using any extra memory.
+
+ The list itself contains list pointers and pointers to data items.
+ Data items contain the following:
+
+ idx - An index that captures the initial order of the list.
+ data - Variable data initialized based on the input parameters. The 16b are divided as follows:
+ o Upper 8b are backup of original data.
+ o Bit 7 indicates if the lower 7 bits are to be used as is or calculated.
+ o Bits 0-2 indicate type of operation to perform to get a 7b value.
+ o Bits 3-6 provide input for the operation.
+
+*/
+
+/* local functions */
+
+list_head *core_list_find(list_head *list,list_data *info);
+list_head *core_list_reverse(list_head *list);
+list_head *core_list_remove(list_head *item);
+list_head *core_list_undo_remove(list_head *item_removed, list_head *item_modified);
+list_head *core_list_insert_new(list_head *insert_point
+ , list_data *info, list_head **memblock, list_data **datablock
+ , list_head *memblock_end, list_data *datablock_end);
+typedef ee_s32(*list_cmp)(list_data *a, list_data *b, core_results *res);
+list_head *core_list_mergesort(list_head *list, list_cmp cmp, core_results *res);
+
+ee_s16 calc_func(ee_s16 *pdata, core_results *res) {
+ ee_s16 data=*pdata;
+ ee_s16 retval;
+ ee_u8 optype=(data>>7) & 1; /* bit 7 indicates if the function result has been cached */
+ if (optype) /* if cached, use cache */
+ return (data & 0x007f);
+ else { /* otherwise calculate and cache the result */
+ ee_s16 flag=data & 0x7; /* bits 0-2 is type of function to perform */
+ ee_s16 dtype=((data>>3) & 0xf); /* bits 3-6 is specific data for the operation */
+ dtype |= dtype << 4; /* replicate the lower 4 bits to get an 8b value */
+ switch (flag) {
+ case 0:
+ if (dtype<0x22) /* set min period for bit corruption */
+ dtype=0x22;
+ retval=core_bench_state(res->size,(ee_u8*) res->memblock[3],res->seed1,res->seed2,dtype,res->crc);
+ if (res->crcstate==0)
+ res->crcstate=retval;
+ break;
+ case 1:
+ retval=core_bench_matrix(&(res->mat),dtype,res->crc);
+ if (res->crcmatrix==0)
+ res->crcmatrix=retval;
+ break;
+ default:
+ retval=data;
+ break;
+ }
+ res->crc=crcu16(retval,res->crc);
+ retval &= 0x007f;
+ *pdata = (data & 0xff00) | 0x0080 | retval; /* cache the result */
+ return retval;
+ }
+}
+/* Function: cmp_complex
+ Compare the data item in a list cell.
+
+ Can be used by mergesort.
+*/
+ee_s32 cmp_complex(list_data *a, list_data *b, core_results *res) {
+ ee_s16 val1=calc_func(&(a->data16),res);
+ ee_s16 val2=calc_func(&(b->data16),res);
+ return val1 - val2;
+}
+
+/* Function: cmp_idx
+ Compare the idx item in a list cell, and regen the data.
+
+ Can be used by mergesort.
+*/
+ee_s32 cmp_idx(list_data *a, list_data *b, core_results *res) {
+ if (res==NULL) {
+ a->data16 = (a->data16 & 0xff00) | (0x00ff & (a->data16>>8));
+ b->data16 = (b->data16 & 0xff00) | (0x00ff & (b->data16>>8));
+ }
+ return a->idx - b->idx;
+}
+
+void copy_info(list_data *to,list_data *from) {
+ to->data16=from->data16;
+ to->idx=from->idx;
+}
+
+/* Benchmark for linked list:
+ - Try to find multiple data items.
+ - List sort
+ - Operate on data from list (crc)
+ - Single remove/reinsert
+ * At the end of this function, the list is back to original state
+*/
+ee_u16 core_bench_list(core_results *res, ee_s16 finder_idx) {
+ ee_u16 retval=0;
+ ee_u16 found=0,missed=0;
+ list_head *list=res->list;
+ ee_s16 find_num=res->seed3;
+ list_head *this_find;
+ list_head *finder, *remover;
+ list_data info;
+ ee_s16 i;
+
+ info.idx=finder_idx;
+ /* find <find_num> values in the list, and change the list each time (reverse and cache if value found) */
+ for (i=0; i<find_num; i++) {
+ info.data16= (i & 0xff) ;
+ this_find=core_list_find(list,&info);
+ list=core_list_reverse(list);
+ if (this_find==NULL) {
+ missed++;
+ retval+=(list->next->info->data16 >> 8) & 1;
+ }
+ else {
+ found++;
+ if (this_find->info->data16 & 0x1) /* use found value */
+ retval+=(this_find->info->data16 >> 9) & 1;
+ /* and cache next item at the head of the list (if any) */
+ if (this_find->next != NULL) {
+ finder = this_find->next;
+ this_find->next = finder->next;
+ finder->next=list->next;
+ list->next=finder;
+ }
+ }
+ if (info.idx>=0)
+ info.idx++;
+#if CORE_DEBUG
+ ee_printf("List find %d: [%d,%d,%d]\n",i,retval,missed,found);
+#endif
+ }
+ retval+=found*4-missed;
+ /* sort the list by data content and remove one item*/
+ if (finder_idx>0)
+ list=core_list_mergesort(list,cmp_complex,res);
+ remover=core_list_remove(list->next);
+ /* CRC data content of list from location of index N forward, and then undo remove */
+ finder=core_list_find(list,&info);
+ if (!finder)
+ finder=list->next;
+ while (finder) {
+ retval=crc16(list->info->data16,retval);
+ finder=finder->next;
+ }
+#if CORE_DEBUG
+ ee_printf("List sort 1: %04x\n",retval);
+#endif
+ remover=core_list_undo_remove(remover,list->next);
+ /* sort the list by index, in effect returning the list to original state */
+ list=core_list_mergesort(list,cmp_idx,NULL);
+ /* CRC data content of list */
+ finder=list->next;
+ while (finder) {
+ retval=crc16(list->info->data16,retval);
+ finder=finder->next;
+ }
+#if CORE_DEBUG
+ ee_printf("List sort 2: %04x\n",retval);
+#endif
+ return retval;
+}
+/* Function: core_list_init
+ Initialize list with data.
+
+ Parameters:
+ blksize - Size of memory to be initialized.
+ memblock - Pointer to memory block.
+ seed - Actual values chosen depend on the seed parameter.
+ The seed parameter MUST be supplied from a source that cannot be determined at compile time
+
+ Returns:
+ Pointer to the head of the list.
+
+*/
+list_head *core_list_init(ee_u32 blksize, list_head *memblock, ee_s16 seed) {
+ /* calculated pointers for the list */
+ ee_u32 per_item=16+sizeof(struct list_data_s);
+ ee_u32 size=(blksize/per_item)-2; /* to accomodate systems with 64b pointers, and make sure same code is executed, set max list elements */
+ list_head *memblock_end=memblock+size;
+ list_data *datablock=(list_data *)(memblock_end);
+ list_data *datablock_end=datablock+size;
+ /* some useful variables */
+ ee_u32 i;
+ list_head *finder,*list=memblock;
+ list_data info;
+
+ /* create a fake items for the list head and tail */
+ list->next=NULL;
+ list->info=datablock;
+ list->info->idx=0x0000;
+ list->info->data16=(ee_s16)0x8080;
+ memblock++;
+ datablock++;
+ info.idx=0x7fff;
+ info.data16=(ee_s16)0xffff;
+ core_list_insert_new(list,&info,&memblock,&datablock,memblock_end,datablock_end);
+
+ /* then insert size items */
+ for (i=0; i<size; i++) {
+ ee_u16 datpat=((ee_u16)(seed^i) & 0xf);
+ ee_u16 dat=(datpat<<3) | (i&0x7); /* alternate between algorithms */
+ info.data16=(dat<<8) | dat; /* fill the data with actual data and upper bits with rebuild value */
+ core_list_insert_new(list,&info,&memblock,&datablock,memblock_end,datablock_end);
+ }
+ /* and now index the list so we know initial seed order of the list */
+ finder=list->next;
+ i=1;
+ while (finder->next!=NULL) {
+ if (i<size/5) /* first 20% of the list in order */
+ finder->info->idx=i++;
+ else {
+ ee_u16 pat=(ee_u16)(i++ ^ seed); /* get a pseudo random number */
+ finder->info->idx=0x3fff & (((i & 0x07) << 8) | pat); /* make sure the mixed items end up after the ones in sequence */
+ }
+ finder=finder->next;
+ }
+ list = core_list_mergesort(list,cmp_idx,NULL);
+#if CORE_DEBUG
+ ee_printf("Initialized list:\n");
+ finder=list;
+ while (finder) {
+ ee_printf("[%04x,%04x]",finder->info->idx,(ee_u16)finder->info->data16);
+ finder=finder->next;
+ }
+ ee_printf("\n");
+#endif
+ return list;
+}
+
+/* Function: core_list_insert
+ Insert an item to the list
+
+ Parameters:
+ insert_point - where to insert the item.
+ info - data for the cell.
+ memblock - pointer for the list header
+ datablock - pointer for the list data
+ memblock_end - end of region for list headers
+ datablock_end - end of region for list data
+
+ Returns:
+ Pointer to new item.
+*/
+list_head *core_list_insert_new(list_head *insert_point, list_data *info, list_head **memblock, list_data **datablock
+ , list_head *memblock_end, list_data *datablock_end) {
+ list_head *newitem;
+
+ if ((*memblock+1) >= memblock_end)
+ return NULL;
+ if ((*datablock+1) >= datablock_end)
+ return NULL;
+
+ newitem=*memblock;
+ (*memblock)++;
+ newitem->next=insert_point->next;
+ insert_point->next=newitem;
+
+ newitem->info=*datablock;
+ (*datablock)++;
+ copy_info(newitem->info,info);
+
+ return newitem;
+}
+
+/* Function: core_list_remove
+ Remove an item from the list.
+
+ Operation:
+ For a singly linked list, remove by copying the data from the next item
+ over to the current cell, and unlinking the next item.
+
+ Note:
+ since there is always a fake item at the end of the list, no need to check for NULL.
+
+ Returns:
+ Removed item.
+*/
+list_head *core_list_remove(list_head *item) {
+ list_data *tmp;
+ list_head *ret=item->next;
+ /* swap data pointers */
+ tmp=item->info;
+ item->info=ret->info;
+ ret->info=tmp;
+ /* and eliminate item */
+ item->next=item->next->next;
+ ret->next=NULL;
+ return ret;
+}
+
+/* Function: core_list_undo_remove
+ Undo a remove operation.
+
+ Operation:
+ Since we want each iteration of the benchmark to be exactly the same,
+ we need to be able to undo a remove.
+ Link the removed item back into the list, and switch the info items.
+
+ Parameters:
+ item_removed - Return value from the <core_list_remove>
+ item_modified - List item that was modified during <core_list_remove>
+
+ Returns:
+ The item that was linked back to the list.
+
+*/
+list_head *core_list_undo_remove(list_head *item_removed, list_head *item_modified) {
+ list_data *tmp;
+ /* swap data pointers */
+ tmp=item_removed->info;
+ item_removed->info=item_modified->info;
+ item_modified->info=tmp;
+ /* and insert item */
+ item_removed->next=item_modified->next;
+ item_modified->next=item_removed;
+ return item_removed;
+}
+
+/* Function: core_list_find
+ Find an item in the list
+
+ Operation:
+ Find an item by idx (if not 0) or specific data value
+
+ Parameters:
+ list - list head
+ info - idx or data to find
+
+ Returns:
+ Found item, or NULL if not found.
+*/
+list_head *core_list_find(list_head *list,list_data *info) {
+ if (info->idx>=0) {
+ while (list && (list->info->idx != info->idx))
+ list=list->next;
+ return list;
+ } else {
+ while (list && ((list->info->data16 & 0xff) != info->data16))
+ list=list->next;
+ return list;
+ }
+}
+/* Function: core_list_reverse
+ Reverse a list
+
+ Operation:
+ Rearrange the pointers so the list is reversed.
+
+ Parameters:
+ list - list head
+ info - idx or data to find
+
+ Returns:
+ Found item, or NULL if not found.
+*/
+
+list_head *core_list_reverse(list_head *list) {
+ list_head *next=NULL, *tmp;
+ while (list) {
+ tmp=list->next;
+ list->next=next;
+ next=list;
+ list=tmp;
+ }
+ return next;
+}
+/* Function: core_list_mergesort
+ Sort the list in place without recursion.
+
+ Description:
+ Use mergesort, as for linked list this is a realistic solution.
+ Also, since this is aimed at embedded, care was taken to use iterative rather then recursive algorithm.
+ The sort can either return the list to original order (by idx) ,
+ or use the data item to invoke other other algorithms and change the order of the list.
+
+ Parameters:
+ list - list to be sorted.
+ cmp - cmp function to use
+
+ Returns:
+ New head of the list.
+
+ Note:
+ We have a special header for the list that will always be first,
+ but the algorithm could theoretically modify where the list starts.
+
+ */
+list_head *core_list_mergesort(list_head *list, list_cmp cmp, core_results *res) {
+ list_head *p, *q, *e, *tail;
+ ee_s32 insize, nmerges, psize, qsize, i;
+
+ insize = 1;
+
+ while (1) {
+ p = list;
+ list = NULL;
+ tail = NULL;
+
+ nmerges = 0; /* count number of merges we do in this pass */
+
+ while (p) {
+ nmerges++; /* there exists a merge to be done */
+ /* step `insize' places along from p */
+ q = p;
+ psize = 0;
+ for (i = 0; i < insize; i++) {
+ psize++;
+ q = q->next;
+ if (!q) break;
+ }
+
+ /* if q hasn't fallen off end, we have two lists to merge */
+ qsize = insize;
+
+ /* now we have two lists; merge them */
+ while (psize > 0 || (qsize > 0 && q)) {
+
+ /* decide whether next element of merge comes from p or q */
+ if (psize == 0) {
+ /* p is empty; e must come from q. */
+ e = q; q = q->next; qsize--;
+ } else if (qsize == 0 || !q) {
+ /* q is empty; e must come from p. */
+ e = p; p = p->next; psize--;
+ } else if (cmp(p->info,q->info,res) <= 0) {
+ /* First element of p is lower (or same); e must come from p. */
+ e = p; p = p->next; psize--;
+ } else {
+ /* First element of q is lower; e must come from q. */
+ e = q; q = q->next; qsize--;
+ }
+
+ /* add the next element to the merged list */
+ if (tail) {
+ tail->next = e;
+ } else {
+ list = e;
+ }
+ tail = e;
+ }
+
+ /* now p has stepped `insize' places along, and q has too */
+ p = q;
+ }
+
+ tail->next = NULL;
+
+ /* If we have done only one merge, we're finished. */
+ if (nmerges <= 1) /* allow for nmerges==0, the empty list case */
+ return list;
+
+ /* Otherwise repeat, merging lists twice the size */
+ insize *= 2;
+ }
+#if COMPILER_REQUIRES_SORT_RETURN
+ return list;
+#endif
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_main.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,356 @@
+/*
+Author : Shay Gal-On, EEMBC
+
+This file is part of EEMBC(R) and CoreMark(TM), which are Copyright (C) 2009
+All rights reserved.
+
+EEMBC CoreMark Software is a product of EEMBC and is provided under the terms of the
+CoreMark License that is distributed with the official EEMBC COREMARK Software release.
+If you received this EEMBC CoreMark Software without the accompanying CoreMark License,
+you must discontinue use and download the official release from www.coremark.org.
+
+Also, if you are publicly displaying scores generated from the EEMBC CoreMark software,
+make sure that you are in compliance with Run and Reporting rules specified in the accompanying readme.txt file.
+
+EEMBC
+4354 Town Center Blvd. Suite 114-200
+El Dorado Hills, CA, 95762
+*/
+/* File: core_main.c
+ This file contains the framework to acquire a block of memory, seed initial parameters, tun t he benchmark and report the results.
+*/
+#include "coremark.h"
+
+/* Function: iterate
+ Run the benchmark for a specified number of iterations.
+
+ Operation:
+ For each type of benchmarked algorithm:
+ a - Initialize the data block for the algorithm.
+ b - Execute the algorithm N times.
+
+ Returns:
+ NULL.
+*/
+static ee_u16 list_known_crc[] = {(ee_u16)0xd4b0,(ee_u16)0x3340,(ee_u16)0x6a79,(ee_u16)0xe714,(ee_u16)0xe3c1};
+static ee_u16 matrix_known_crc[] = {(ee_u16)0xbe52,(ee_u16)0x1199,(ee_u16)0x5608,(ee_u16)0x1fd7,(ee_u16)0x0747};
+static ee_u16 state_known_crc[] = {(ee_u16)0x5e47,(ee_u16)0x39bf,(ee_u16)0xe5a4,(ee_u16)0x8e3a,(ee_u16)0x8d84};
+void *iterate(void *pres) {
+ ee_u32 i;
+ ee_u16 crc;
+ core_results *res=(core_results *)pres;
+ ee_u32 iterations=res->iterations;
+ res->crc=0;
+ res->crclist=0;
+ res->crcmatrix=0;
+ res->crcstate=0;
+
+ for (i=0; i<iterations; i++) {
+ crc=core_bench_list(res,1);
+ res->crc=crcu16(crc,res->crc);
+ crc=core_bench_list(res,-1);
+ res->crc=crcu16(crc,res->crc);
+ if (i==0) res->crclist=res->crc;
+ }
+ return NULL;
+}
+
+#if (SEED_METHOD==SEED_ARG)
+ee_s32 get_seed_args(int i, int argc, char *argv[]);
+#define get_seed(x) (ee_s16)get_seed_args(x,argc,argv)
+#define get_seed_32(x) get_seed_args(x,argc,argv)
+#else /* via function or volatile */
+ee_s32 get_seed_32(int i);
+#define get_seed(x) (ee_s16)get_seed_32(x)
+#endif
+
+#if (MEM_METHOD==MEM_STATIC)
+ee_u8 static_memblk[TOTAL_DATA_SIZE];
+#endif
+char *mem_name[3] = {"Static","Heap","Stack"};
+/* Function: main
+ Main entry routine for the benchmark.
+ This function is responsible for the following steps:
+
+ 1 - Initialize input seeds from a source that cannot be determined at compile time.
+ 2 - Initialize memory block for use.
+ 3 - Run and time the benchmark.
+ 4 - Report results, testing the validity of the output if the seeds are known.
+
+ Arguments:
+ 1 - first seed : Any value
+ 2 - second seed : Must be identical to first for iterations to be identical
+ 3 - third seed : Any value, should be at least an order of magnitude less then the input size, but bigger then 32.
+ 4 - Iterations : Special, if set to 0, iterations will be automatically determined such that the benchmark will run between 10 to 100 secs
+
+*/
+
+#if MAIN_HAS_NOARGC
+MAIN_RETURN_TYPE mainCoreMark(void) {
+ int argc=0;
+ char *argv[1];
+#else
+MAIN_RETURN_TYPE mainCoreMark(int argc, char *argv[]) {
+#endif
+ ee_u16 i,j=0,num_algorithms=0;
+ ee_s16 known_id=-1,total_errors=0;
+ ee_u16 seedcrc=0;
+ CORE_TICKS total_time;
+ core_results results[MULTITHREAD];
+#if (MEM_METHOD==MEM_STACK)
+ ee_u8 stack_memblock[TOTAL_DATA_SIZE*MULTITHREAD];
+#endif
+ /* first call any initializations needed */
+ portable_init(&(results[0].port), &argc, argv);
+ /* First some checks to make sure benchmark will run ok */
+ if (sizeof(struct list_head_s)>128) {
+ ee_printf("list_head structure too big for comparable data!\n");
+ return MAIN_RETURN_VAL;
+ }
+ results[0].seed1=get_seed(1);
+ results[0].seed2=get_seed(2);
+ results[0].seed3=get_seed(3);
+ results[0].iterations=get_seed_32(4);
+#if CORE_DEBUG
+ results[0].iterations=1;
+#endif
+ results[0].execs=get_seed_32(5);
+ if (results[0].execs==0) { /* if not supplied, execute all algorithms */
+ results[0].execs=ALL_ALGORITHMS_MASK;
+ }
+ /* put in some default values based on one seed only for easy testing */
+ if ((results[0].seed1==0) && (results[0].seed2==0) && (results[0].seed3==0)) { /* validation run */
+ results[0].seed1=0;
+ results[0].seed2=0;
+ results[0].seed3=0x66;
+ }
+ if ((results[0].seed1==1) && (results[0].seed2==0) && (results[0].seed3==0)) { /* perfromance run */
+ results[0].seed1=0x3415;
+ results[0].seed2=0x3415;
+ results[0].seed3=0x66;
+ }
+#if (MEM_METHOD==MEM_STATIC)
+ results[0].memblock[0]=(void *)static_memblk;
+ results[0].size=TOTAL_DATA_SIZE;
+ results[0].err=0;
+ #if (MULTITHREAD>1)
+ #error "Cannot use a static data area with multiple contexts!"
+ #endif
+#elif (MEM_METHOD==MEM_MALLOC)
+ for (i=0 ; i<MULTITHREAD; i++) {
+ ee_s32 malloc_override=get_seed(7);
+ if (malloc_override != 0)
+ results[i].size=malloc_override;
+ else
+ results[i].size=TOTAL_DATA_SIZE;
+ results[i].memblock[0]=portable_malloc(results[i].size);
+ results[i].seed1=results[0].seed1;
+ results[i].seed2=results[0].seed2;
+ results[i].seed3=results[0].seed3;
+ results[i].err=0;
+ results[i].execs=results[0].execs;
+ }
+#elif (MEM_METHOD==MEM_STACK)
+ for (i=0 ; i<MULTITHREAD; i++) {
+ results[i].memblock[0]=stack_memblock+i*TOTAL_DATA_SIZE;
+ results[i].size=TOTAL_DATA_SIZE;
+ results[i].seed1=results[0].seed1;
+ results[i].seed2=results[0].seed2;
+ results[i].seed3=results[0].seed3;
+ results[i].err=0;
+ results[i].execs=results[0].execs;
+ }
+#else
+#error "Please define a way to initialize a memory block."
+#endif
+ /* Data init */
+ /* Find out how space much we have based on number of algorithms */
+ for (i=0; i<NUM_ALGORITHMS; i++) {
+ if ((1<<(ee_u32)i) & results[0].execs)
+ num_algorithms++;
+ }
+ for (i=0 ; i<MULTITHREAD; i++)
+ results[i].size=results[i].size/num_algorithms;
+ /* Assign pointers */
+ for (i=0; i<NUM_ALGORITHMS; i++) {
+ ee_u32 ctx;
+ if ((1<<(ee_u32)i) & results[0].execs) {
+ for (ctx=0 ; ctx<MULTITHREAD; ctx++)
+ results[ctx].memblock[i+1]=(char *)(results[ctx].memblock[0])+results[0].size*j;
+ j++;
+ }
+ }
+ /* call inits */
+ for (i=0 ; i<MULTITHREAD; i++) {
+ if (results[i].execs & ID_LIST) {
+ results[i].list=core_list_init(results[0].size, (list_head*) results[i].memblock[1],results[i].seed1);
+ }
+ if (results[i].execs & ID_MATRIX) {
+ core_init_matrix(results[0].size, results[i].memblock[2], (ee_s32)results[i].seed1 | (((ee_s32)results[i].seed2) << 16), &(results[i].mat) );
+ }
+ if (results[i].execs & ID_STATE) {
+ core_init_state(results[0].size,results[i].seed1, (ee_u8*) results[i].memblock[3]);
+ }
+ }
+
+ /* automatically determine number of iterations if not set */
+ if (results[0].iterations==0) {
+ secs_ret secs_passed=0;
+ ee_u32 divisor;
+ results[0].iterations=1;
+ while (secs_passed < (secs_ret)1) {
+ results[0].iterations*=10;
+ start_time();
+ iterate(&results[0]);
+ stop_time();
+ secs_passed=time_in_secs(get_time());
+ }
+ /* now we know it executes for at least 1 sec, set actual run time at about 10 secs */
+ divisor=(ee_u32)secs_passed;
+ if (divisor==0) /* some machines cast float to int as 0 since this conversion is not defined by ANSI, but we know at least one second passed */
+ divisor=1;
+ results[0].iterations*=1+10/divisor;
+ }
+ /* perform actual benchmark */
+ start_time();
+#if (MULTITHREAD>1)
+ if (default_num_contexts>MULTITHREAD) {
+ default_num_contexts=MULTITHREAD;
+ }
+ for (i=0 ; i<default_num_contexts; i++) {
+ results[i].iterations=results[0].iterations;
+ results[i].execs=results[0].execs;
+ core_start_parallel(&results[i]);
+ }
+ for (i=0 ; i<default_num_contexts; i++) {
+ core_stop_parallel(&results[i]);
+ }
+#else
+ iterate(&results[0]);
+#endif
+ stop_time();
+ total_time=get_time();
+ /* get a function of the input to report */
+ seedcrc=crc16(results[0].seed1,seedcrc);
+ seedcrc=crc16(results[0].seed2,seedcrc);
+ seedcrc=crc16(results[0].seed3,seedcrc);
+ seedcrc=crc16(results[0].size,seedcrc);
+
+ switch (seedcrc) { /* test known output for common seeds */
+ case 0x8a02: /* seed1=0, seed2=0, seed3=0x66, size 2000 per algorithm */
+ known_id=0;
+ ee_printf("6k performance run parameters for coremark.\n");
+ break;
+ case 0x7b05: /* seed1=0x3415, seed2=0x3415, seed3=0x66, size 2000 per algorithm */
+ known_id=1;
+ ee_printf("6k validation run parameters for coremark.\n");
+ break;
+ case 0x4eaf: /* seed1=0x8, seed2=0x8, seed3=0x8, size 400 per algorithm */
+ known_id=2;
+ ee_printf("Profile generation run parameters for coremark.\n");
+ break;
+ case 0xe9f5: /* seed1=0, seed2=0, seed3=0x66, size 666 per algorithm */
+ known_id=3;
+ ee_printf("2K performance run parameters for coremark.\n");
+ break;
+ case 0x18f2: /* seed1=0x3415, seed2=0x3415, seed3=0x66, size 666 per algorithm */
+ known_id=4;
+ ee_printf("2K validation run parameters for coremark.\n");
+ break;
+ default:
+ total_errors=-1;
+ break;
+ }
+ if (known_id>=0) {
+ for (i=0 ; i<default_num_contexts; i++) {
+ results[i].err=0;
+ if ((results[i].execs & ID_LIST) &&
+ (results[i].crclist!=list_known_crc[known_id])) {
+ ee_printf("[%u]ERROR! list crc 0x%04x - should be 0x%04x\n",i,results[i].crclist,list_known_crc[known_id]);
+ results[i].err++;
+ }
+ if ((results[i].execs & ID_MATRIX) &&
+ (results[i].crcmatrix!=matrix_known_crc[known_id])) {
+ ee_printf("[%u]ERROR! matrix crc 0x%04x - should be 0x%04x\n",i,results[i].crcmatrix,matrix_known_crc[known_id]);
+ results[i].err++;
+ }
+ if ((results[i].execs & ID_STATE) &&
+ (results[i].crcstate!=state_known_crc[known_id])) {
+ ee_printf("[%u]ERROR! state crc 0x%04x - should be 0x%04x\n",i,results[i].crcstate,state_known_crc[known_id]);
+ results[i].err++;
+ }
+ total_errors+=results[i].err;
+ }
+ }
+ total_errors+=check_data_types();
+ /* and report results */
+ ee_printf("CoreMark Size : %lu\n",(ee_u32)results[0].size);
+ ee_printf("Total ticks : %lu\n",(ee_u32)total_time);
+#if HAS_FLOAT
+ ee_printf("Total time (secs): %f\n",time_in_secs(total_time));
+ if (time_in_secs(total_time) > 0)
+ ee_printf("Iterations/Sec : %f\n",default_num_contexts*results[0].iterations/time_in_secs(total_time));
+#else
+ ee_printf("Total time (secs): %d\n",time_in_secs(total_time));
+ if (time_in_secs(total_time) > 0)
+ ee_printf("Iterations/Sec : %d\n",default_num_contexts*results[0].iterations/time_in_secs(total_time));
+#endif
+ if (time_in_secs(total_time) < 10) {
+ ee_printf("ERROR! Must execute for at least 10 secs for a valid result!\n");
+ total_errors++;
+ }
+
+ ee_printf("Iterations : %lu\n",(ee_u32)default_num_contexts*results[0].iterations);
+ ee_printf("Compiler version : %s\n",COMPILER_VERSION);
+ ee_printf("Compiler flags : %s\n",COMPILER_FLAGS);
+#if (MULTITHREAD>1)
+ ee_printf("Parallel %s : %d\n",PARALLEL_METHOD,default_num_contexts);
+#endif
+ ee_printf("Memory location : %s\n",MEM_LOCATION);
+ /* output for verification */
+ ee_printf("seedcrc : 0x%04x\n",seedcrc);
+ if (results[0].execs & ID_LIST)
+ for (i=0 ; i<default_num_contexts; i++)
+ ee_printf("[%d]crclist : 0x%04x\n",i,results[i].crclist);
+ if (results[0].execs & ID_MATRIX)
+ for (i=0 ; i<default_num_contexts; i++)
+ ee_printf("[%d]crcmatrix : 0x%04x\n",i,results[i].crcmatrix);
+ if (results[0].execs & ID_STATE)
+ for (i=0 ; i<default_num_contexts; i++)
+ ee_printf("[%d]crcstate : 0x%04x\n",i,results[i].crcstate);
+ for (i=0 ; i<default_num_contexts; i++)
+ ee_printf("[%d]crcfinal : 0x%04x\n",i,results[i].crc);
+ if (total_errors==0) {
+ ee_printf("Correct operation validated. See readme.txt for run and reporting rules.\n");
+#if HAS_FLOAT
+ if (known_id==3) {
+ ee_printf("CoreMark 1.0 : %f / %s %s",default_num_contexts*results[0].iterations/time_in_secs(total_time),COMPILER_VERSION,COMPILER_FLAGS);
+#if defined(MEM_LOCATION) && !defined(MEM_LOCATION_UNSPEC)
+ ee_printf(" / %s",MEM_LOCATION);
+#else
+ ee_printf(" / %s",mem_name[MEM_METHOD]);
+#endif
+
+#if (MULTITHREAD>1)
+ ee_printf(" / %d:%s",default_num_contexts,PARALLEL_METHOD);
+#endif
+ ee_printf("\n");
+ }
+#endif
+ }
+ if (total_errors>0)
+ ee_printf("Errors detected\n");
+ if (total_errors<0)
+ ee_printf("Cannot validate operation for these seed values, please compare with results on a known platform.\n");
+
+#if (MEM_METHOD==MEM_MALLOC)
+ for (i=0 ; i<MULTITHREAD; i++)
+ portable_free(results[i].memblock[0]);
+#endif
+ /* And last call any target specific code for finalizing */
+ portable_fini(&(results[0].port));
+
+ return MAIN_RETURN_VAL;
+}
+
+
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_matrix.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,308 @@
+/*
+Author : Shay Gal-On, EEMBC
+
+This file is part of EEMBC(R) and CoreMark(TM), which are Copyright (C) 2009
+All rights reserved.
+
+EEMBC CoreMark Software is a product of EEMBC and is provided under the terms of the
+CoreMark License that is distributed with the official EEMBC COREMARK Software release.
+If you received this EEMBC CoreMark Software without the accompanying CoreMark License,
+you must discontinue use and download the official release from www.coremark.org.
+
+Also, if you are publicly displaying scores generated from the EEMBC CoreMark software,
+make sure that you are in compliance with Run and Reporting rules specified in the accompanying readme.txt file.
+
+EEMBC
+4354 Town Center Blvd. Suite 114-200
+El Dorado Hills, CA, 95762
+*/
+#include "coremark.h"
+/*
+Topic: Description
+ Matrix manipulation benchmark
+
+ This very simple algorithm forms the basis of many more complex algorithms.
+
+ The tight inner loop is the focus of many optimizations (compiler as well as hardware based)
+ and is thus relevant for embedded processing.
+
+ The total available data space will be divided to 3 parts:
+ NxN Matrix A - initialized with small values (upper 3/4 of the bits all zero).
+ NxN Matrix B - initialized with medium values (upper half of the bits all zero).
+ NxN Matrix C - used for the result.
+
+ The actual values for A and B must be derived based on input that is not available at compile time.
+*/
+ee_s16 matrix_test(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B, MATDAT val);
+ee_s16 matrix_sum(ee_u32 N, MATRES *C, MATDAT clipval);
+void matrix_mul_const(ee_u32 N, MATRES *C, MATDAT *A, MATDAT val);
+void matrix_mul_vect(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B);
+void matrix_mul_matrix(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B);
+void matrix_mul_matrix_bitextract(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B);
+void matrix_add_const(ee_u32 N, MATDAT *A, MATDAT val);
+
+#define matrix_test_next(x) (x+1)
+#define matrix_clip(x,y) ((y) ? (x) & 0x0ff : (x) & 0x0ffff)
+#define matrix_big(x) (0xf000 | (x))
+#define bit_extract(x,from,to) (((x)>>(from)) & (~(0xffffffff << (to))))
+
+#if CORE_DEBUG
+void printmat(MATDAT *A, ee_u32 N, char *name) {
+ ee_u32 i,j;
+ ee_printf("Matrix %s [%dx%d]:\n",name,N,N);
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ if (j!=0)
+ ee_printf(",");
+ ee_printf("%d",A[i*N+j]);
+ }
+ ee_printf("\n");
+ }
+}
+void printmatC(MATRES *C, ee_u32 N, char *name) {
+ ee_u32 i,j;
+ ee_printf("Matrix %s [%dx%d]:\n",name,N,N);
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ if (j!=0)
+ ee_printf(",");
+ ee_printf("%d",C[i*N+j]);
+ }
+ ee_printf("\n");
+ }
+}
+#endif
+/* Function: core_bench_matrix
+ Benchmark function
+
+ Iterate <matrix_test> N times,
+ changing the matrix values slightly by a constant amount each time.
+*/
+ee_u16 core_bench_matrix(mat_params *p, ee_s16 seed, ee_u16 crc) {
+ ee_u32 N=p->N;
+ MATRES *C=p->C;
+ MATDAT *A=p->A;
+ MATDAT *B=p->B;
+ MATDAT val=(MATDAT)seed;
+
+ crc=crc16(matrix_test(N,C,A,B,val),crc);
+
+ return crc;
+}
+
+/* Function: matrix_test
+ Perform matrix manipulation.
+
+ Parameters:
+ N - Dimensions of the matrix.
+ C - memory for result matrix.
+ A - input matrix
+ B - operator matrix (not changed during operations)
+
+ Returns:
+ A CRC value that captures all results calculated in the function.
+ In particular, crc of the value calculated on the result matrix
+ after each step by <matrix_sum>.
+
+ Operation:
+
+ 1 - Add a constant value to all elements of a matrix.
+ 2 - Multiply a matrix by a constant.
+ 3 - Multiply a matrix by a vector.
+ 4 - Multiply a matrix by a matrix.
+ 5 - Add a constant value to all elements of a matrix.
+
+ After the last step, matrix A is back to original contents.
+*/
+ee_s16 matrix_test(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B, MATDAT val) {
+ ee_u16 crc=0;
+ MATDAT clipval=matrix_big(val);
+
+ matrix_add_const(N,A,val); /* make sure data changes */
+#if CORE_DEBUG
+ printmat(A,N,"matrix_add_const");
+#endif
+ matrix_mul_const(N,C,A,val);
+ crc=crc16(matrix_sum(N,C,clipval),crc);
+#if CORE_DEBUG
+ printmatC(C,N,"matrix_mul_const");
+#endif
+ matrix_mul_vect(N,C,A,B);
+ crc=crc16(matrix_sum(N,C,clipval),crc);
+#if CORE_DEBUG
+ printmatC(C,N,"matrix_mul_vect");
+#endif
+ matrix_mul_matrix(N,C,A,B);
+ crc=crc16(matrix_sum(N,C,clipval),crc);
+#if CORE_DEBUG
+ printmatC(C,N,"matrix_mul_matrix");
+#endif
+ matrix_mul_matrix_bitextract(N,C,A,B);
+ crc=crc16(matrix_sum(N,C,clipval),crc);
+#if CORE_DEBUG
+ printmatC(C,N,"matrix_mul_matrix_bitextract");
+#endif
+
+ matrix_add_const(N,A,-val); /* return matrix to initial value */
+ return crc;
+}
+
+/* Function : matrix_init
+ Initialize the memory block for matrix benchmarking.
+
+ Parameters:
+ blksize - Size of memory to be initialized.
+ memblk - Pointer to memory block.
+ seed - Actual values chosen depend on the seed parameter.
+ p - pointers to <mat_params> containing initialized matrixes.
+
+ Returns:
+ Matrix dimensions.
+
+ Note:
+ The seed parameter MUST be supplied from a source that cannot be determined at compile time
+*/
+ee_u32 core_init_matrix(ee_u32 blksize, void *memblk, ee_s32 seed, mat_params *p) {
+ ee_u32 N=0;
+ MATDAT *A;
+ MATDAT *B;
+ ee_s32 order=1;
+ MATDAT val;
+ ee_u32 i=0,j=0;
+ if (seed==0)
+ seed=1;
+ while (j<blksize) {
+ i++;
+ j=i*i*2*4;
+ }
+ N=i-1;
+ A=(MATDAT *)align_mem(memblk);
+ B=A+N*N;
+
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ seed = ( ( order * seed ) % 65536 );
+ val = (seed + order);
+ val=matrix_clip(val,0);
+ B[i*N+j] = val;
+ val = (val + order);
+ val=matrix_clip(val,1);
+ A[i*N+j] = val;
+ order++;
+ }
+ }
+
+ p->A=A;
+ p->B=B;
+ p->C=(MATRES *)align_mem(B+N*N);
+ p->N=N;
+#if CORE_DEBUG
+ printmat(A,N,"A");
+ printmat(B,N,"B");
+#endif
+ return N;
+}
+
+/* Function: matrix_sum
+ Calculate a function that depends on the values of elements in the matrix.
+
+ For each element, accumulate into a temporary variable.
+
+ As long as this value is under the parameter clipval,
+ add 1 to the result if the element is bigger then the previous.
+
+ Otherwise, reset the accumulator and add 10 to the result.
+*/
+ee_s16 matrix_sum(ee_u32 N, MATRES *C, MATDAT clipval) {
+ MATRES tmp=0,prev=0,cur=0;
+ ee_s16 ret=0;
+ ee_u32 i,j;
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ cur=C[i*N+j];
+ tmp+=cur;
+ if (tmp>clipval) {
+ ret+=10;
+ tmp=0;
+ } else {
+ ret += (cur>prev) ? 1 : 0;
+ }
+ prev=cur;
+ }
+ }
+ return ret;
+}
+
+/* Function: matrix_mul_const
+ Multiply a matrix by a constant.
+ This could be used as a scaler for instance.
+*/
+void matrix_mul_const(ee_u32 N, MATRES *C, MATDAT *A, MATDAT val) {
+ ee_u32 i,j;
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ C[i*N+j]=(MATRES)A[i*N+j] * (MATRES)val;
+ }
+ }
+}
+
+/* Function: matrix_add_const
+ Add a constant value to all elements of a matrix.
+*/
+void matrix_add_const(ee_u32 N, MATDAT *A, MATDAT val) {
+ ee_u32 i,j;
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ A[i*N+j] += val;
+ }
+ }
+}
+
+/* Function: matrix_mul_vect
+ Multiply a matrix by a vector.
+ This is common in many simple filters (e.g. fir where a vector of coefficients is applied to the matrix.)
+*/
+void matrix_mul_vect(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B) {
+ ee_u32 i,j;
+ for (i=0; i<N; i++) {
+ C[i]=0;
+ for (j=0; j<N; j++) {
+ C[i]+=(MATRES)A[i*N+j] * (MATRES)B[j];
+ }
+ }
+}
+
+/* Function: matrix_mul_matrix
+ Multiply a matrix by a matrix.
+ Basic code is used in many algorithms, mostly with minor changes such as scaling.
+*/
+void matrix_mul_matrix(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B) {
+ ee_u32 i,j,k;
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ C[i*N+j]=0;
+ for(k=0;k<N;k++)
+ {
+ C[i*N+j]+=(MATRES)A[i*N+k] * (MATRES)B[k*N+j];
+ }
+ }
+ }
+}
+
+/* Function: matrix_mul_matrix_bitextract
+ Multiply a matrix by a matrix, and extract some bits from the result.
+ Basic code is used in many algorithms, mostly with minor changes such as scaling.
+*/
+void matrix_mul_matrix_bitextract(ee_u32 N, MATRES *C, MATDAT *A, MATDAT *B) {
+ ee_u32 i,j,k;
+ for (i=0; i<N; i++) {
+ for (j=0; j<N; j++) {
+ C[i*N+j]=0;
+ for(k=0;k<N;k++)
+ {
+ MATRES tmp=(MATRES)A[i*N+k] * (MATRES)B[k*N+j];
+ C[i*N+j]+=bit_extract(tmp,2,4)*bit_extract(tmp,5,7);
+ }
+ }
+ }
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_portme.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,121 @@
+/*
+ File : core_portme.c
+*/
+/*
+ Author : Shay Gal-On, EEMBC
+ Legal : TODO!
+*/
+#include "coremark.h"
+#include "core_portme.h"
+#include "mbed.h"
+
+
+#if VALIDATION_RUN
+ volatile ee_s32 seed1_volatile=0x3415;
+ volatile ee_s32 seed2_volatile=0x3415;
+ volatile ee_s32 seed3_volatile=0x66;
+#endif
+#if PERFORMANCE_RUN
+ volatile ee_s32 seed1_volatile=0x0;
+ volatile ee_s32 seed2_volatile=0x0;
+ volatile ee_s32 seed3_volatile=0x66;
+#endif
+#if PROFILE_RUN
+ volatile ee_s32 seed1_volatile=0x8;
+ volatile ee_s32 seed2_volatile=0x8;
+ volatile ee_s32 seed3_volatile=0x8;
+#endif
+ volatile ee_s32 seed4_volatile=ITERATIONS;
+ volatile ee_s32 seed5_volatile=0;
+/* Porting : Timing functions
+ How to capture time and convert to seconds must be ported to whatever is supported by the platform.
+ e.g. Read value from on board RTC, read value from cpu clock cycles performance counter etc.
+ Sample implementation for standard time.h and windows.h definitions included.
+*/
+
+CORETIMETYPE barebones_clock() {
+ return clock();
+}
+/* Define : TIMER_RES_DIVIDER
+ Divider to trade off timer resolution and total time that can be measured.
+
+ Use lower values to increase resolution, but make sure that overflow does not occur.
+ If there are issues with the return value overflowing, increase this value.
+ */
+#define GETMYTIME(_t) (*_t=barebones_clock())
+#define MYTIMEDIFF(fin,ini) ((fin)-(ini))
+#define TIMER_RES_DIVIDER 1
+#define SAMPLE_TIME_IMPLEMENTATION 1
+#define EE_TICKS_PER_SEC (CLOCKS_PER_SEC / TIMER_RES_DIVIDER)
+
+/** Define Host specific (POSIX), or target specific global time variables. */
+static CORETIMETYPE start_time_val, stop_time_val;
+
+/* Function : start_time
+ This function will be called right before starting the timed portion of the benchmark.
+
+ Implementation may be capturing a system timer (as implemented in the example code)
+ or zeroing some system parameters - e.g. setting the cpu clocks cycles to 0.
+*/
+void start_time(void) {
+ GETMYTIME(&start_time_val );
+}
+/* Function : stop_time
+ This function will be called right after ending the timed portion of the benchmark.
+
+ Implementation may be capturing a system timer (as implemented in the example code)
+ or other system parameters - e.g. reading the current value of cpu cycles counter.
+*/
+void stop_time(void) {
+ GETMYTIME(&stop_time_val );
+}
+/* Function : get_time
+ Return an abstract "ticks" number that signifies time on the system.
+
+ Actual value returned may be cpu cycles, milliseconds or any other value,
+ as long as it can be converted to seconds by <time_in_secs>.
+ This methodology is taken to accomodate any hardware or simulated platform.
+ The sample implementation returns millisecs by default,
+ and the resolution is controlled by <TIMER_RES_DIVIDER>
+*/
+CORE_TICKS get_time(void) {
+ CORE_TICKS elapsed=(CORE_TICKS)(MYTIMEDIFF(stop_time_val, start_time_val));
+ return elapsed;
+}
+/* Function : time_in_secs
+ Convert the value returned by get_time to seconds.
+
+ The <secs_ret> type is used to accomodate systems with no support for floating point.
+ Default implementation implemented by the EE_TICKS_PER_SEC macro above.
+*/
+secs_ret time_in_secs(CORE_TICKS ticks) {
+ secs_ret retval=((secs_ret)ticks) / (secs_ret)EE_TICKS_PER_SEC;
+ return retval;
+}
+
+ee_u32 default_num_contexts=1;
+
+/* Function : portable_init
+ Target specific initialization code
+ Test for some common mistakes.
+*/
+void portable_init(core_portable *p, int *argc, char *argv[])
+{
+ //#error "Call board initialization routines in portable init (if needed), in particular initialize UART!\n"
+ if (sizeof(ee_ptr_int) != sizeof(ee_u8 *)) {
+ ee_printf("ERROR! Please define ee_ptr_int to a type that holds a pointer!\n");
+ }
+ if (sizeof(ee_u32) != 4) {
+ ee_printf("ERROR! Please define ee_u32 to a 32b unsigned type!\n");
+ }
+ p->portable_id=1;
+}
+/* Function : portable_fini
+ Target specific final code
+*/
+void portable_fini(core_portable *p)
+{
+ p->portable_id=0;
+}
+
+
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_portme.h Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,191 @@
+/* File : core_portme.h */
+
+/*
+ Author : Shay Gal-On, EEMBC
+ Legal : TODO!
+*/
+/* Topic : Description
+ This file contains configuration constants required to execute on different platforms
+*/
+
+#ifndef CORE_PORTME_H
+#define CORE_PORTME_H
+
+#define ITERATIONS 5000
+int mainCoreMark(void); //to start coremark from main program
+
+#include <stddef.h> // for size_t
+/************************/
+/* Data types and settings */
+/************************/
+/* Configuration : HAS_FLOAT
+ Define to 1 if the platform supports floating point.
+*/
+#ifndef HAS_FLOAT
+#define HAS_FLOAT 1
+#endif
+/* Configuration : HAS_TIME_H
+ Define to 1 if platform has the time.h header file,
+ and implementation of functions thereof.
+*/
+#ifndef HAS_TIME_H
+#define HAS_TIME_H 0
+#endif
+/* Configuration : USE_CLOCK
+ Define to 1 if platform has the time.h header file,
+ and implementation of functions thereof.
+*/
+#ifndef USE_CLOCK
+#define USE_CLOCK 0
+#endif
+/* Configuration : HAS_STDIO
+ Define to 1 if the platform has stdio.h.
+*/
+#ifndef HAS_STDIO
+#define HAS_STDIO 1
+#endif
+/* Configuration : HAS_PRINTF
+ Define to 1 if the platform has stdio.h and implements the printf function.
+*/
+#ifndef HAS_PRINTF
+#define HAS_PRINTF 1
+#endif
+
+
+/* Definitions : COMPILER_VERSION, COMPILER_FLAGS, MEM_LOCATION
+ Initialize these strings per platform
+*/
+#ifndef COMPILER_VERSION
+ #ifdef __GNUC__
+ #define COMPILER_VERSION __VERSION__
+ #else
+ #define COMPILER_VERSION "Please put compiler version here (e.g. gcc 4.1)"
+ #endif
+#endif
+#ifndef COMPILER_FLAGS
+ #define COMPILER_FLAGS ""/* "Please put compiler flags here (e.g. -o3)" */
+#endif
+#ifndef MEM_LOCATION
+ #define MEM_LOCATION "STACK"
+#endif
+
+/* Data Types :
+ To avoid compiler issues, define the data types that need ot be used for 8b, 16b and 32b in <core_portme.h>.
+
+ *Imprtant* :
+ ee_ptr_int needs to be the data type used to hold pointers, otherwise coremark may fail!!!
+*/
+typedef signed short ee_s16;
+typedef unsigned short ee_u16;
+typedef signed int ee_s32;
+typedef double ee_f32;
+typedef unsigned char ee_u8;
+typedef unsigned int ee_u32;
+typedef ee_u32 ee_ptr_int;
+typedef size_t ee_size_t;
+/* align_mem :
+ This macro is used to align an offset to point to a 32b value. It is used in the Matrix algorithm to initialize the input memory blocks.
+*/
+#define align_mem(x) (void *)(4 + (((ee_ptr_int)(x) - 1) & ~3))
+
+/* Configuration : CORE_TICKS
+ Define type of return from the timing functions.
+ */
+#define CORETIMETYPE ee_u32
+typedef ee_u32 CORE_TICKS;
+
+/* Configuration : SEED_METHOD
+ Defines method to get seed values that cannot be computed at compile time.
+
+ Valid values :
+ SEED_ARG - from command line.
+ SEED_FUNC - from a system function.
+ SEED_VOLATILE - from volatile variables.
+*/
+#ifndef SEED_METHOD
+#define SEED_METHOD SEED_VOLATILE
+#endif
+
+/* Configuration : MEM_METHOD
+ Defines method to get a block of memry.
+
+ Valid values :
+ MEM_MALLOC - for platforms that implement malloc and have malloc.h.
+ MEM_STATIC - to use a static memory array.
+ MEM_STACK - to allocate the data block on the stack (NYI).
+*/
+#ifndef MEM_METHOD
+#define MEM_METHOD MEM_STACK
+#endif
+
+/* Configuration : MULTITHREAD
+ Define for parallel execution
+
+ Valid values :
+ 1 - only one context (default).
+ N>1 - will execute N copies in parallel.
+
+ Note :
+ If this flag is defined to more then 1, an implementation for launching parallel contexts must be defined.
+
+ Two sample implementations are provided. Use <USE_PTHREAD> or <USE_FORK> to enable them.
+
+ It is valid to have a different implementation of <core_start_parallel> and <core_end_parallel> in <core_portme.c>,
+ to fit a particular architecture.
+*/
+#ifndef MULTITHREAD
+#define MULTITHREAD 1
+#define USE_PTHREAD 0
+#define USE_FORK 0
+#define USE_SOCKET 0
+#endif
+
+/* Configuration : MAIN_HAS_NOARGC
+ Needed if platform does not support getting arguments to main.
+
+ Valid values :
+ 0 - argc/argv to main is supported
+ 1 - argc/argv to main is not supported
+
+ Note :
+ This flag only matters if MULTITHREAD has been defined to a value greater then 1.
+*/
+#ifndef MAIN_HAS_NOARGC
+#define MAIN_HAS_NOARGC 1
+#endif
+
+/* Configuration : MAIN_HAS_NORETURN
+ Needed if platform does not support returning a value from main.
+
+ Valid values :
+ 0 - main returns an int, and return value will be 0.
+ 1 - platform does not support returning a value from main
+*/
+#ifndef MAIN_HAS_NORETURN
+#define MAIN_HAS_NORETURN 0
+#endif
+
+/* Variable : default_num_contexts
+ Not used for this simple port, must cintain the value 1.
+*/
+extern ee_u32 default_num_contexts;
+
+typedef struct CORE_PORTABLE_S {
+ ee_u8 portable_id;
+} core_portable;
+
+/* target specific init/fini */
+void portable_init(core_portable *p, int *argc, char *argv[]);
+void portable_fini(core_portable *p);
+
+#if !defined(PROFILE_RUN) && !defined(PERFORMANCE_RUN) && !defined(VALIDATION_RUN)
+#if (TOTAL_DATA_SIZE==1200)
+#define PROFILE_RUN 1
+#elif (TOTAL_DATA_SIZE==2000)
+#define PERFORMANCE_RUN 1
+#else
+#define VALIDATION_RUN 1
+#endif
+#endif
+
+#endif /* CORE_PORTME_H */
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_state.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,277 @@
+/*
+Author : Shay Gal-On, EEMBC
+
+This file is part of EEMBC(R) and CoreMark(TM), which are Copyright (C) 2009
+All rights reserved.
+
+EEMBC CoreMark Software is a product of EEMBC and is provided under the terms of the
+CoreMark License that is distributed with the official EEMBC COREMARK Software release.
+If you received this EEMBC CoreMark Software without the accompanying CoreMark License,
+you must discontinue use and download the official release from www.coremark.org.
+
+Also, if you are publicly displaying scores generated from the EEMBC CoreMark software,
+make sure that you are in compliance with Run and Reporting rules specified in the accompanying readme.txt file.
+
+EEMBC
+4354 Town Center Blvd. Suite 114-200
+El Dorado Hills, CA, 95762
+*/
+#include "coremark.h"
+/* local functions */
+enum CORE_STATE core_state_transition( ee_u8 **instr , ee_u32 *transition_count);
+
+/*
+Topic: Description
+ Simple state machines like this one are used in many embedded products.
+
+ For more complex state machines, sometimes a state transition table implementation is used instead,
+ trading speed of direct coding for ease of maintenance.
+
+ Since the main goal of using a state machine in CoreMark is to excercise the switch/if behaviour,
+ we are using a small moore machine.
+
+ In particular, this machine tests type of string input,
+ trying to determine whether the input is a number or something else.
+ (see core_state.png).
+*/
+
+/* Function: core_bench_state
+ Benchmark function
+
+ Go over the input twice, once direct, and once after introducing some corruption.
+*/
+ee_u16 core_bench_state(ee_u32 blksize, ee_u8 *memblock,
+ ee_s16 seed1, ee_s16 seed2, ee_s16 step, ee_u16 crc)
+{
+ ee_u32 final_counts[NUM_CORE_STATES];
+ ee_u32 track_counts[NUM_CORE_STATES];
+ ee_u8 *p=memblock;
+ ee_u32 i;
+
+
+#if CORE_DEBUG
+ ee_printf("State Bench: %d,%d,%d,%04x\n",seed1,seed2,step,crc);
+#endif
+ for (i=0; i<NUM_CORE_STATES; i++) {
+ final_counts[i]=track_counts[i]=0;
+ }
+ /* run the state machine over the input */
+ while (*p!=0) {
+ enum CORE_STATE fstate=core_state_transition(&p,track_counts);
+ final_counts[fstate]++;
+#if CORE_DEBUG
+ ee_printf("%d,",fstate);
+ }
+ ee_printf("\n");
+#else
+ }
+#endif
+ p=memblock;
+ while (p < (memblock+blksize)) { /* insert some corruption */
+ if (*p!=',')
+ *p^=(ee_u8)seed1;
+ p+=step;
+ }
+ p=memblock;
+ /* run the state machine over the input again */
+ while (*p!=0) {
+ enum CORE_STATE fstate=core_state_transition(&p,track_counts);
+ final_counts[fstate]++;
+#if CORE_DEBUG
+ ee_printf("%d,",fstate);
+ }
+ ee_printf("\n");
+#else
+ }
+#endif
+ p=memblock;
+ while (p < (memblock+blksize)) { /* undo corruption is seed1 and seed2 are equal */
+ if (*p!=',')
+ *p^=(ee_u8)seed2;
+ p+=step;
+ }
+ /* end timing */
+ for (i=0; i<NUM_CORE_STATES; i++) {
+ crc=crcu32(final_counts[i],crc);
+ crc=crcu32(track_counts[i],crc);
+ }
+ return crc;
+}
+
+/* Default initialization patterns */
+static ee_u8 *intpat[4] ={(ee_u8 *)"5012",(ee_u8 *)"1234",(ee_u8 *)"-874",(ee_u8 *)"+122"};
+static ee_u8 *floatpat[4]={(ee_u8 *)"35.54400",(ee_u8 *)".1234500",(ee_u8 *)"-110.700",(ee_u8 *)"+0.64400"};
+static ee_u8 *scipat[4] ={(ee_u8 *)"5.500e+3",(ee_u8 *)"-.123e-2",(ee_u8 *)"-87e+832",(ee_u8 *)"+0.6e-12"};
+static ee_u8 *errpat[4] ={(ee_u8 *)"T0.3e-1F",(ee_u8 *)"-T.T++Tq",(ee_u8 *)"1T3.4e4z",(ee_u8 *)"34.0e-T^"};
+
+/* Function: core_init_state
+ Initialize the input data for the state machine.
+
+ Populate the input with several predetermined strings, interspersed.
+ Actual patterns chosen depend on the seed parameter.
+
+ Note:
+ The seed parameter MUST be supplied from a source that cannot be determined at compile time
+*/
+void core_init_state(ee_u32 size, ee_s16 seed, ee_u8 *p) {
+ ee_u32 total=0,next=0,i;
+ ee_u8 *buf=0;
+#if CORE_DEBUG
+ ee_u8 *start=p;
+ ee_printf("State: %d,%d\n",size,seed);
+#endif
+ size--;
+ next=0;
+ while ((total+next+1)<size) {
+ if (next>0) {
+ for(i=0;i<next;i++)
+ *(p+total+i)=buf[i];
+ *(p+total+i)=',';
+ total+=next+1;
+ }
+ seed++;
+ switch (seed & 0x7) {
+ case 0: /* int */
+ case 1: /* int */
+ case 2: /* int */
+ buf=intpat[(seed>>3) & 0x3];
+ next=4;
+ break;
+ case 3: /* float */
+ case 4: /* float */
+ buf=floatpat[(seed>>3) & 0x3];
+ next=8;
+ break;
+ case 5: /* scientific */
+ case 6: /* scientific */
+ buf=scipat[(seed>>3) & 0x3];
+ next=8;
+ break;
+ case 7: /* invalid */
+ buf=errpat[(seed>>3) & 0x3];
+ next=8;
+ break;
+ default: /* Never happen, just to make some compilers happy */
+ break;
+ }
+ }
+ size++;
+ while (total<size) { /* fill the rest with 0 */
+ *(p+total)=0;
+ total++;
+ }
+#if CORE_DEBUG
+ ee_printf("State Input: %s\n",start);
+#endif
+}
+
+static ee_u8 ee_isdigit(ee_u8 c) {
+ ee_u8 retval;
+ retval = ((c>='0') & (c<='9')) ? 1 : 0;
+ return retval;
+}
+
+/* Function: core_state_transition
+ Actual state machine.
+
+ The state machine will continue scanning until either:
+ 1 - an invalid input is detcted.
+ 2 - a valid number has been detected.
+
+ The input pointer is updated to point to the end of the token, and the end state is returned (either specific format determined or invalid).
+*/
+
+enum CORE_STATE core_state_transition( ee_u8 **instr , ee_u32 *transition_count) {
+ ee_u8 *str=*instr;
+ ee_u8 NEXT_SYMBOL;
+ enum CORE_STATE state=CORE_START;
+ for( ; *str && state != CORE_INVALID; str++ ) {
+ NEXT_SYMBOL = *str;
+ if (NEXT_SYMBOL==',') /* end of this input */ {
+ str++;
+ break;
+ }
+ switch(state) {
+ case CORE_START:
+ if(ee_isdigit(NEXT_SYMBOL)) {
+ state = CORE_INT;
+ }
+ else if( NEXT_SYMBOL == '+' || NEXT_SYMBOL == '-' ) {
+ state = CORE_S1;
+ }
+ else if( NEXT_SYMBOL == '.' ) {
+ state = CORE_FLOAT;
+ }
+ else {
+ state = CORE_INVALID;
+ transition_count[CORE_INVALID]++;
+ }
+ transition_count[CORE_START]++;
+ break;
+ case CORE_S1:
+ if(ee_isdigit(NEXT_SYMBOL)) {
+ state = CORE_INT;
+ transition_count[CORE_S1]++;
+ }
+ else if( NEXT_SYMBOL == '.' ) {
+ state = CORE_FLOAT;
+ transition_count[CORE_S1]++;
+ }
+ else {
+ state = CORE_INVALID;
+ transition_count[CORE_S1]++;
+ }
+ break;
+ case CORE_INT:
+ if( NEXT_SYMBOL == '.' ) {
+ state = CORE_FLOAT;
+ transition_count[CORE_INT]++;
+ }
+ else if(!ee_isdigit(NEXT_SYMBOL)) {
+ state = CORE_INVALID;
+ transition_count[CORE_INT]++;
+ }
+ break;
+ case CORE_FLOAT:
+ if( NEXT_SYMBOL == 'E' || NEXT_SYMBOL == 'e' ) {
+ state = CORE_S2;
+ transition_count[CORE_FLOAT]++;
+ }
+ else if(!ee_isdigit(NEXT_SYMBOL)) {
+ state = CORE_INVALID;
+ transition_count[CORE_FLOAT]++;
+ }
+ break;
+ case CORE_S2:
+ if( NEXT_SYMBOL == '+' || NEXT_SYMBOL == '-' ) {
+ state = CORE_EXPONENT;
+ transition_count[CORE_S2]++;
+ }
+ else {
+ state = CORE_INVALID;
+ transition_count[CORE_S2]++;
+ }
+ break;
+ case CORE_EXPONENT:
+ if(ee_isdigit(NEXT_SYMBOL)) {
+ state = CORE_SCIENTIFIC;
+ transition_count[CORE_EXPONENT]++;
+ }
+ else {
+ state = CORE_INVALID;
+ transition_count[CORE_EXPONENT]++;
+ }
+ break;
+ case CORE_SCIENTIFIC:
+ if(!ee_isdigit(NEXT_SYMBOL)) {
+ state = CORE_INVALID;
+ transition_count[CORE_INVALID]++;
+ }
+ break;
+ default:
+ break;
+ }
+ }
+ *instr=str;
+ return state;
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/core_util.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,210 @@
+/*
+Author : Shay Gal-On, EEMBC
+
+This file is part of EEMBC(R) and CoreMark(TM), which are Copyright (C) 2009
+All rights reserved.
+
+EEMBC CoreMark Software is a product of EEMBC and is provided under the terms of the
+CoreMark License that is distributed with the official EEMBC COREMARK Software release.
+If you received this EEMBC CoreMark Software without the accompanying CoreMark License,
+you must discontinue use and download the official release from www.coremark.org.
+
+Also, if you are publicly displaying scores generated from the EEMBC CoreMark software,
+make sure that you are in compliance with Run and Reporting rules specified in the accompanying readme.txt file.
+
+EEMBC
+4354 Town Center Blvd. Suite 114-200
+El Dorado Hills, CA, 95762
+*/
+#include "coremark.h"
+/* Function: get_seed
+ Get a values that cannot be determined at compile time.
+
+ Since different embedded systems and compilers are used, 3 different methods are provided:
+ 1 - Using a volatile variable. This method is only valid if the compiler is forced to generate code that
+ reads the value of a volatile variable from memory at run time.
+ Please note, if using this method, you would need to modify core_portme.c to generate training profile.
+ 2 - Command line arguments. This is the preferred method if command line arguments are supported.
+ 3 - System function. If none of the first 2 methods is available on the platform,
+ a system function which is not a stub can be used.
+
+ e.g. read the value on GPIO pins connected to switches, or invoke special simulator functions.
+*/
+#if (SEED_METHOD==SEED_VOLATILE)
+ extern volatile ee_s32 seed1_volatile;
+ extern volatile ee_s32 seed2_volatile;
+ extern volatile ee_s32 seed3_volatile;
+ extern volatile ee_s32 seed4_volatile;
+ extern volatile ee_s32 seed5_volatile;
+ ee_s32 get_seed_32(int i) {
+ ee_s32 retval;
+ switch (i) {
+ case 1:
+ retval=seed1_volatile;
+ break;
+ case 2:
+ retval=seed2_volatile;
+ break;
+ case 3:
+ retval=seed3_volatile;
+ break;
+ case 4:
+ retval=seed4_volatile;
+ break;
+ case 5:
+ retval=seed5_volatile;
+ break;
+ default:
+ retval=0;
+ break;
+ }
+ return retval;
+ }
+#elif (SEED_METHOD==SEED_ARG)
+ee_s32 parseval(char *valstring) {
+ ee_s32 retval=0;
+ ee_s32 neg=1;
+ int hexmode=0;
+ if (*valstring == '-') {
+ neg=-1;
+ valstring++;
+ }
+ if ((valstring[0] == '0') && (valstring[1] == 'x')) {
+ hexmode=1;
+ valstring+=2;
+ }
+ /* first look for digits */
+ if (hexmode) {
+ while (((*valstring >= '0') && (*valstring <= '9')) || ((*valstring >= 'a') && (*valstring <= 'f'))) {
+ ee_s32 digit=*valstring-'0';
+ if (digit>9)
+ digit=10+*valstring-'a';
+ retval*=16;
+ retval+=digit;
+ valstring++;
+ }
+ } else {
+ while ((*valstring >= '0') && (*valstring <= '9')) {
+ ee_s32 digit=*valstring-'0';
+ retval*=10;
+ retval+=digit;
+ valstring++;
+ }
+ }
+ /* now add qualifiers */
+ if (*valstring=='K')
+ retval*=1024;
+ if (*valstring=='M')
+ retval*=1024*1024;
+
+ retval*=neg;
+ return retval;
+}
+
+ee_s32 get_seed_args(int i, int argc, char *argv[]) {
+ if (argc>i)
+ return parseval(argv[i]);
+ return 0;
+}
+
+#elif (SEED_METHOD==SEED_FUNC)
+/* If using OS based function, you must define and implement the functions below in core_portme.h and core_portme.c ! */
+ee_s32 get_seed_32(int i) {
+ ee_s32 retval;
+ switch (i) {
+ case 1:
+ retval=portme_sys1();
+ break;
+ case 2:
+ retval=portme_sys2();
+ break;
+ case 3:
+ retval=portme_sys3();
+ break;
+ case 4:
+ retval=portme_sys4();
+ break;
+ case 5:
+ retval=portme_sys5();
+ break;
+ default:
+ retval=0;
+ break;
+ }
+ return retval;
+}
+#endif
+
+/* Function: crc*
+ Service functions to calculate 16b CRC code.
+
+*/
+ee_u16 crcu8(ee_u8 data, ee_u16 crc )
+{
+ ee_u8 i=0,x16=0,carry=0;
+
+ for (i = 0; i < 8; i++)
+ {
+ x16 = (ee_u8)((data & 1) ^ ((ee_u8)crc & 1));
+ data >>= 1;
+
+ if (x16 == 1)
+ {
+ crc ^= 0x4002;
+ carry = 1;
+ }
+ else
+ carry = 0;
+ crc >>= 1;
+ if (carry)
+ crc |= 0x8000;
+ else
+ crc &= 0x7fff;
+ }
+ return crc;
+}
+ee_u16 crcu16(ee_u16 newval, ee_u16 crc) {
+ crc=crcu8( (ee_u8) (newval) ,crc);
+ crc=crcu8( (ee_u8) ((newval)>>8) ,crc);
+ return crc;
+}
+ee_u16 crcu32(ee_u32 newval, ee_u16 crc) {
+ crc=crc16((ee_s16) newval ,crc);
+ crc=crc16((ee_s16) (newval>>16) ,crc);
+ return crc;
+}
+ee_u16 crc16(ee_s16 newval, ee_u16 crc) {
+ return crcu16((ee_u16)newval, crc);
+}
+
+ee_u8 check_data_types() {
+ ee_u8 retval=0;
+ if (sizeof(ee_u8) != 1) {
+ ee_printf("ERROR: ee_u8 is not an 8b datatype!\n");
+ retval++;
+ }
+ if (sizeof(ee_u16) != 2) {
+ ee_printf("ERROR: ee_u16 is not a 16b datatype!\n");
+ retval++;
+ }
+ if (sizeof(ee_s16) != 2) {
+ ee_printf("ERROR: ee_s16 is not a 16b datatype!\n");
+ retval++;
+ }
+ if (sizeof(ee_s32) != 4) {
+ ee_printf("ERROR: ee_s32 is not a 32b datatype!\n");
+ retval++;
+ }
+ if (sizeof(ee_u32) != 4) {
+ ee_printf("ERROR: ee_u32 is not a 32b datatype!\n");
+ retval++;
+ }
+ if (sizeof(ee_ptr_int) != sizeof(int *)) {
+ ee_printf("ERROR: ee_ptr_int is not a datatype that holds an int pointer!\n");
+ retval++;
+ }
+ if (retval>0) {
+ ee_printf("ERROR: Please modify the datatypes in core_portme.h!\n");
+ }
+ return retval;
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/coremark.h Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,174 @@
+/*
+Author : Shay Gal-On, EEMBC
+
+This file is part of EEMBC(R) and CoreMark(TM), which are Copyright (C) 2009
+All rights reserved.
+
+EEMBC CoreMark Software is a product of EEMBC and is provided under the terms of the
+CoreMark License that is distributed with the official EEMBC COREMARK Software release.
+If you received this EEMBC CoreMark Software without the accompanying CoreMark License,
+you must discontinue use and download the official release from www.coremark.org.
+
+Also, if you are publicly displaying scores generated from the EEMBC CoreMark software,
+make sure that you are in compliance with Run and Reporting rules specified in the accompanying readme.txt file.
+
+EEMBC
+4354 Town Center Blvd. Suite 114-200
+El Dorado Hills, CA, 95762
+*/
+/* Topic: Description
+ This file contains declarations of the various benchmark functions.
+*/
+
+/* Configuration: TOTAL_DATA_SIZE
+ Define total size for data algorithms will operate on
+*/
+#ifndef TOTAL_DATA_SIZE
+#define TOTAL_DATA_SIZE 2*1000
+#endif
+
+#define SEED_ARG 0
+#define SEED_FUNC 1
+#define SEED_VOLATILE 2
+
+#define MEM_STATIC 0
+#define MEM_MALLOC 1
+#define MEM_STACK 2
+
+#include "core_portme.h"
+
+#if HAS_STDIO
+#include <stdio.h>
+#endif
+#if HAS_PRINTF
+#define ee_printf printf
+#endif
+
+/* Actual benchmark execution in iterate */
+void *iterate(void *pres);
+
+/* Typedef: secs_ret
+ For machines that have floating point support, get number of seconds as a double.
+ Otherwise an unsigned int.
+*/
+#if HAS_FLOAT
+typedef double secs_ret;
+#else
+typedef ee_u32 secs_ret;
+#endif
+
+#if MAIN_HAS_NORETURN
+#define MAIN_RETURN_VAL
+#define MAIN_RETURN_TYPE void
+#else
+#define MAIN_RETURN_VAL 0
+#define MAIN_RETURN_TYPE int
+#endif
+
+void start_time(void);
+void stop_time(void);
+CORE_TICKS get_time(void);
+secs_ret time_in_secs(CORE_TICKS ticks);
+
+/* Misc useful functions */
+ee_u16 crcu8(ee_u8 data, ee_u16 crc);
+ee_u16 crc16(ee_s16 newval, ee_u16 crc);
+ee_u16 crcu16(ee_u16 newval, ee_u16 crc);
+ee_u16 crcu32(ee_u32 newval, ee_u16 crc);
+ee_u8 check_data_types();
+void *portable_malloc(ee_size_t size);
+void portable_free(void *p);
+ee_s32 parseval(char *valstring);
+
+/* Algorithm IDS */
+#define ID_LIST (1<<0)
+#define ID_MATRIX (1<<1)
+#define ID_STATE (1<<2)
+#define ALL_ALGORITHMS_MASK (ID_LIST|ID_MATRIX|ID_STATE)
+#define NUM_ALGORITHMS 3
+
+/* list data structures */
+typedef struct list_data_s {
+ ee_s16 data16;
+ ee_s16 idx;
+} list_data;
+
+typedef struct list_head_s {
+ struct list_head_s *next;
+ struct list_data_s *info;
+} list_head;
+
+
+/*matrix benchmark related stuff */
+#define MATDAT_INT 1
+#if MATDAT_INT
+typedef ee_s16 MATDAT;
+typedef ee_s32 MATRES;
+#else
+typedef ee_f16 MATDAT;
+typedef ee_f32 MATRES;
+#endif
+
+typedef struct MAT_PARAMS_S {
+ int N;
+ MATDAT *A;
+ MATDAT *B;
+ MATRES *C;
+} mat_params;
+
+/* state machine related stuff */
+/* List of all the possible states for the FSM */
+typedef enum CORE_STATE {
+ CORE_START=0,
+ CORE_INVALID,
+ CORE_S1,
+ CORE_S2,
+ CORE_INT,
+ CORE_FLOAT,
+ CORE_EXPONENT,
+ CORE_SCIENTIFIC,
+ NUM_CORE_STATES
+} core_state_e ;
+
+
+/* Helper structure to hold results */
+typedef struct RESULTS_S {
+ /* inputs */
+ ee_s16 seed1; /* Initializing seed */
+ ee_s16 seed2; /* Initializing seed */
+ ee_s16 seed3; /* Initializing seed */
+ void *memblock[4]; /* Pointer to safe memory location */
+ ee_u32 size; /* Size of the data */
+ ee_u32 iterations; /* Number of iterations to execute */
+ ee_u32 execs; /* Bitmask of operations to execute */
+ struct list_head_s *list;
+ mat_params mat;
+ /* outputs */
+ ee_u16 crc;
+ ee_u16 crclist;
+ ee_u16 crcmatrix;
+ ee_u16 crcstate;
+ ee_s16 err;
+ /* ultithread specific */
+ core_portable port;
+} core_results;
+
+/* Multicore execution handling */
+#if (MULTITHREAD>1)
+ee_u8 core_start_parallel(core_results *res);
+ee_u8 core_stop_parallel(core_results *res);
+#endif
+
+/* list benchmark functions */
+list_head *core_list_init(ee_u32 blksize, list_head *memblock, ee_s16 seed);
+ee_u16 core_bench_list(core_results *res, ee_s16 finder_idx);
+
+/* state benchmark functions */
+void core_init_state(ee_u32 size, ee_s16 seed, ee_u8 *p);
+ee_u16 core_bench_state(ee_u32 blksize, ee_u8 *memblock,
+ ee_s16 seed1, ee_s16 seed2, ee_s16 step, ee_u16 crc);
+
+/* matrix benchmark functions */
+ee_u32 core_init_matrix(ee_u32 blksize, void *memblk, ee_s32 seed, mat_params *p);
+ee_u16 core_bench_matrix(mat_params *p, ee_s16 seed, ee_u16 crc);
+
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/CoreMark/cvt.c Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,102 @@
+#include <math.h>
+#define CVTBUFSIZE 80
+static char CVTBUF[CVTBUFSIZE];
+
+static char *cvt(double arg, int ndigits, int *decpt, int *sign, char *buf, int eflag)
+{
+ int r2;
+ double fi, fj;
+ char *p, *p1;
+
+ if (ndigits < 0) ndigits = 0;
+ if (ndigits >= CVTBUFSIZE - 1) ndigits = CVTBUFSIZE - 2;
+ r2 = 0;
+ *sign = 0;
+ p = &buf[0];
+ if (arg < 0)
+ {
+ *sign = 1;
+ arg = -arg;
+ }
+ arg = modf(arg, &fi);
+ p1 = &buf[CVTBUFSIZE];
+
+ if (fi != 0)
+ {
+ p1 = &buf[CVTBUFSIZE];
+ while (fi != 0)
+ {
+ fj = modf(fi / 10, &fi);
+ *--p1 = (int)((fj + .03) * 10) + '0';
+ r2++;
+ }
+ while (p1 < &buf[CVTBUFSIZE]) *p++ = *p1++;
+ }
+ else if (arg > 0)
+ {
+ while ((fj = arg * 10) < 1)
+ {
+ arg = fj;
+ r2--;
+ }
+ }
+ p1 = &buf[ndigits];
+ if (eflag == 0) p1 += r2;
+ *decpt = r2;
+ if (p1 < &buf[0])
+ {
+ buf[0] = '\0';
+ return buf;
+ }
+ while (p <= p1 && p < &buf[CVTBUFSIZE])
+ {
+ arg *= 10;
+ arg = modf(arg, &fj);
+ *p++ = (int) fj + '0';
+ }
+ if (p1 >= &buf[CVTBUFSIZE])
+ {
+ buf[CVTBUFSIZE - 1] = '\0';
+ return buf;
+ }
+ p = p1;
+ *p1 += 5;
+ while (*p1 > '9')
+ {
+ *p1 = '0';
+ if (p1 > buf)
+ ++*--p1;
+ else
+ {
+ *p1 = '1';
+ (*decpt)++;
+ if (eflag == 0)
+ {
+ if (p > buf) *p = '0';
+ p++;
+ }
+ }
+ }
+ *p = '\0';
+ return buf;
+}
+
+char *ecvt(double arg, int ndigits, int *decpt, int *sign)
+{
+ return cvt(arg, ndigits, decpt, sign, CVTBUF, 1);
+}
+
+char *ecvtbuf(double arg, int ndigits, int *decpt, int *sign, char *buf)
+{
+ return cvt(arg, ndigits, decpt, sign, buf, 1);
+}
+
+char *fcvt(double arg, int ndigits, int *decpt, int *sign)
+{
+ return cvt(arg, ndigits, decpt, sign, CVTBUF, 0);
+}
+
+char *fcvtbuf(double arg, int ndigits, int *decpt, int *sign, char *buf)
+{
+ return cvt(arg, ndigits, decpt, sign, buf, 0);
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000
+++ b/main.cpp Sun Jan 24 15:46:26 2010 +0000
@@ -0,0 +1,61 @@
+#include "mbed.h"
+#include "ClockControl/ClockControl.h"
+#include "CoreMark/core_portme.h"
+
+int main() {
+ while(1) {
+
+
+ printf("mbed Clock Control test\r\n");
+ printf("(c) 2010 Michael Wei\r\n");
+
+ unsigned short newM = 12;
+ unsigned short newN = 1;
+
+ printf("Value of M? (default = 12):\r\n");
+ scanf("%d", &newM);
+
+ printf("Value of N? (default = 1):\r\n");
+ scanf("%d", &newN);
+
+ setSystemFrequency(0x3, 0x1, newM, newN);
+
+ Serial pc(USBTX, USBRX); // tx, rx
+
+ //This code by Simon Ford: http://mbed.org/forum/mbed/topic/229/?page=1#comment-1225
+
+ int Fin = 12000000; // 12MHz XTAL
+ pc.printf("PLL Registers:\r\n");
+ pc.printf(" - PLL0CFG = 0x%08X\r\n", LPC_SC->PLL0CFG);
+ pc.printf(" - CLKCFG = 0x%08X\r\n", LPC_SC->CCLKCFG);
+
+ int M = (LPC_SC->PLL0CFG & 0xFFFF) + 1;
+ int N = (LPC_SC->PLL0CFG >> 16) + 1;
+ int CCLKDIV = LPC_SC->CCLKCFG + 1;
+
+ pc.printf("Clock Variables:\r\n");
+ pc.printf(" - Fin = %d\r\n", Fin);
+ pc.printf(" - M = %d\r\n", M);
+ pc.printf(" - N = %d\r\n", N);
+ pc.printf(" - CCLKDIV = %d\r\n", CCLKDIV);
+
+ int Fcco = (2 * M * 12000000) / N;
+ int CCLK = Fcco / CCLKDIV;
+
+ pc.printf("Clock Results:\r\n");
+ pc.printf(" - Fcco = %d\r\n", Fcco);
+
+ printf(" - CCLK = %d\r\n", CCLK);
+
+ printf("Run CoreMark? (Y/N)\n");
+ char buf[8];
+ scanf("%s", buf);
+ if (buf[0] == 'y' || buf[0] == 'Y')
+ {
+ mainCoreMark();
+ }
+
+ wait(1);
+ NVIC_SystemReset();
+ }
+}
--- /dev/null Thu Jan 01 00:00:00 1970 +0000 +++ b/mbed.bld Sun Jan 24 15:46:26 2010 +0000 @@ -0,0 +1,1 @@ +http://mbed.org/users/mbed_official/code/mbed/builds/49a220cc26e0