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Diffstat (limited to 'utils/prof/cgprof/cgprof.c')
| -rw-r--r-- | utils/prof/cgprof/cgprof.c | 1284 |
1 files changed, 1284 insertions, 0 deletions
diff --git a/utils/prof/cgprof/cgprof.c b/utils/prof/cgprof/cgprof.c new file mode 100644 index 0000000000..8ee66e1f52 --- /dev/null +++ b/utils/prof/cgprof/cgprof.c @@ -0,0 +1,1284 @@ +/* ------------------------------------------------------------------------ + * $Id: cgprof.c,v 1.6 2004/08/13 13:11:22 simonmar Exp $ + * + * Copyright (C) 1995-2000 University of Oxford + * + * Permission to use, copy, modify, and distribute this software, + * and to incorporate it, in whole or in part, into other software, + * is hereby granted without fee, provided that + * (1) the above copyright notice and this permission notice appear in + * all copies of the source code, and the above copyright notice + * appear in clearly visible form on all supporting documentation + * and distribution media; + * (2) modified versions of this software be accompanied by a complete + * change history describing author, date, and modifications made; + * and + * (3) any redistribution of the software, in original or modified + * form, be without fee and subject to these same conditions. + * --------------------------------------------------------------------- */ + +#include "ghcconfig.h" +#if HAVE_STRING_H +#include <string.h> +#endif + +#include "daVinci.h" +#include "symbol.h" +#include "cgprof.h" +#include "matrix.h" + +/* ----------------------------------------------------------------------------- + * Data structures + * -------------------------------------------------------------------------- */ + +int raw_profile_next=0; +int raw_profile_size=0; +parsed_cost_object *raw_profile=NULL; + +/* ----------------------------------------------------------------------------- + * Create/grow data sequence of raw profile data + * -------------------------------------------------------------------------- */ + +void enlargeRawProfile() { + + if (raw_profile_size==0) { + raw_profile_next = 0; + raw_profile_size = RAW_PROFILE_INIT_SIZE; + raw_profile = calloc(raw_profile_size,sizeof(parsed_cost_object)); + } else { + raw_profile_size += RAW_PROFILE_INIT_SIZE; + raw_profile = realloc(raw_profile, + raw_profile_size*sizeof(parsed_cost_object)); + } + if (raw_profile==NULL) { + fprintf(stderr,"{enlargeRawProfile} unable to allocate %d elements", + raw_profile_size); + exit(1); + } +} + +/* ----------------------------------------------------------------------------- + * Function that adds two cost centers together + * + * This will be used to generate the inheretance profile. + * -------------------------------------------------------------------------- */ + +void add_costs(object_cost *left, object_cost right) { + + left->syncs += right.syncs; + left->comp_max += right.comp_max; + left->comp_avg += right.comp_avg; + left->comp_min += right.comp_min; + left->comm_max += right.comm_max; + left->comm_avg += right.comm_avg; + left->comm_min += right.comm_min; + left->comp_idle_max += right.comp_idle_max; + left->comp_idle_avg += right.comp_idle_avg; + left->comp_idle_min += right.comp_idle_min; + left->hrel_max += right.hrel_max; + left->hrel_avg += right.hrel_avg; + left->hrel_min += right.hrel_min; + if ((left->proc==NULL) || (right.proc==NULL)) { + fprintf(stderr,"Cost is null"); + exit(0); + } +} + + +int ignore_function(char *fname) { + return 0; +} + +/* ----------------------------------------------------------------------------- + * GHC specific data structures + * -------------------------------------------------------------------------- */ + +/* Globals */ +/* You will need to update these when you increase the number of */ +/* cost centres, cost centre stacks, heap objects */ + + #define MAX_IDENTIFIERS 2000 /* maximum number of identifiers */ + /* or size of matrix structure */ + + /* make this dynamic */ + + #define MAX_TIME 100 /* Maximum serial time for heap profile */ + #define MAX_SAMPLES 50 /* Maximum heap samples */ + + /* To do: modify this to be dynamic */ + + #define MAX_STRING_SIZE 70 + #define MAX_LINE_LENGTH 80 + #define EOF (-1) + +/* Cost centre data structure */ + + struct cost_centre { char *name; + char *module; + char *group; + } _cc_; + + typedef struct cost_centre cc_matrix[MAX_IDENTIFIERS]; + + //typedef struct cost_centre *cc_matrix; + + typedef cc_matrix* p_cc_matrix; + typedef char* MY_STRING; + +/* Heap sample structure */ + + struct heap_sample { + int count; /* heap_sample */ + }; + + typedef struct heap_sample heap_sample_matrix[MAX_IDENTIFIERS]; + typedef heap_sample_matrix* p_heap_sample_matrix; + +/* Cost centre stack data structure */ + + struct cost_centre_stack { + int cc; + int ccs; + int scc; /* scc_sample */ + int ticks; /* scc_sample */ + int bytes; /* scc_sample */ + p_heap_sample_matrix hsm; /* heap_sample */ + }; + + typedef struct cost_centre_stack ccs_matrix[MAX_IDENTIFIERS]; + typedef ccs_matrix* p_ccs_matrix; + +/* Heap object data structure */ + + struct heap_object { int type; /* type of heap object */ + char* descriptor; + int type_constr_ref; /* if present */ + }; + + typedef struct heap_object heap_object_matrix[MAX_IDENTIFIERS]; + typedef heap_object_matrix* p_heap_object_matrix; + +/* Type constructor structure */ + + struct type_constr { char* module; + char* name; + }; + + typedef struct type_constr type_constr_matrix[MAX_IDENTIFIERS]; + typedef type_constr_matrix* p_type_constr_matrix; + +/* Heap update structure */ + + struct heap_update_sample { int ccs; /* associated cost centre stack */ + int ho; /* associated heap object */ + int count; + }; + + typedef struct heap_update_sample heap_update_list[MAX_SAMPLES]; + typedef heap_update_list* p_heap_update_list; + + struct heap_update_record { int no_samples; /* Number of samples */ + p_heap_update_list acc_samples; + }; + + typedef struct heap_update_record TheHeap[MAX_TIME]; + typedef TheHeap* p_TheHeap; + + +/* ----------------------------------------------------------------------------- + * GHC specific functions + * -------------------------------------------------------------------------- */ + +// Initialisation routines + +void initialise_heap_update_list(heap_update_list *m) +{ + int i; + for (i=0; i<MAX_SAMPLES;i++) + { + (*m)[i].ccs = -1; + (*m)[i].ho = -1; + (*m)[i].count = -1; + } +} + +void add_to_heap_update_list(heap_update_list *m, int ccs, int ho, int count, int pos) +{ + (*m)[pos].ccs = ccs; + (*m)[pos].ho = ho; + (*m)[pos].count = count; +} + +void initialise_TheHeap(TheHeap *h) +{ + int i; + for (i=0; i<MAX_TIME;i++) + { + heap_update_list *h_u_l; + h_u_l = (p_heap_update_list) malloc (sizeof(heap_update_list)); + initialise_heap_update_list(h_u_l); + (*h)[i].acc_samples = h_u_l; + (*h)[i].no_samples = 0; + } +} + +void add_to_TheHeap(TheHeap *h, int time, int ccs, int ho, int count) +{ + add_to_heap_update_list((*h)[time].acc_samples,ccs,ho,count,(*h)[time].no_samples); + (*h)[time].no_samples++; +} + +void initialise_cc_matrix(cc_matrix *m) +{ + int i; + char *blank="blank"; /* To do: Modify this terminator string */ + for (i=0; i<MAX_IDENTIFIERS; i++) + { + (*m)[i].name = (MY_STRING) malloc ((MAX_STRING_SIZE)); + (*m)[i].module = (MY_STRING) malloc ((MAX_STRING_SIZE)); + (*m)[i].group = (MY_STRING) malloc ((MAX_STRING_SIZE)); + + strcpy((*m)[i].name,blank); + strcpy((*m)[i].module,blank); + strcpy((*m)[i].group,blank); + } +} + +void free_cc_matrix(cc_matrix *m) +{ + int i; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + free((*m)[i].name); + free((*m)[i].module); + free((*m)[i].group); + } + free(m); +} + +void initialise_heap_object_matrix(heap_object_matrix *m) +{ + int i; + char *blank="blank"; /* To do: ditto */ + for (i=0; i<MAX_IDENTIFIERS; i++) + { + (*m)[i].type = -1; + (*m)[i].descriptor = (MY_STRING) malloc ((MAX_STRING_SIZE)); + strcpy((*m)[i].descriptor,blank); + (*m)[i].type_constr_ref = -1; + } +} + +void initialise_type_constr_matrix(type_constr_matrix *m) +{ + int i; + char *blank="blank"; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + (*m)[i].module = (MY_STRING) malloc ((MAX_STRING_SIZE)); + (*m)[i].name = (MY_STRING) malloc ((MAX_STRING_SIZE)); + strcpy((*m)[i].module,blank); + strcpy((*m)[i].name,blank); + } +} + +void initialise_heap_sample_matrix(heap_sample_matrix *m) +{ + int i; + for (i=0; i<MAX_IDENTIFIERS; i++) + { (*m)[i].count = -1; } +} + +void initialise_ccs_matrix(ccs_matrix *m) +{ + int i; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + /* Stack heap samples */ + heap_sample_matrix *hs_m; + hs_m = (p_heap_sample_matrix) malloc (sizeof(heap_sample_matrix)); + initialise_heap_sample_matrix(hs_m); + (*m)[i].hsm = hs_m; + /* Stack scc samples */ + (*m)[i].cc = 0; + (*m)[i].ccs = 0; + (*m)[i].scc = 0; + (*m)[i].ticks = 0; + (*m)[i].bytes = 0; + } +} + + +// Filling matrix routines + +char* StripDoubleQuotes(char* s) /* For fussy daVinci! */ +{ + char *p = s; + char *tempchar; + char *empty=""; + char *tempstring = (MY_STRING) malloc ((MAX_STRING_SIZE)); + strcpy(tempstring,empty); + while (*p) + { if (*p!='"') + { tempchar = p; strncat(tempstring,p,1); + } + p++; + } + return tempstring; +} + +void fill_cc_matrix(cc_matrix *m,char* name,char* module,char* group,int i) +{ + if (i>MAX_IDENTIFIERS) + { fprintf(logFile,"Cost centre MAX_IDENTIFIERS exceeded: %i \n",i); exit(1); } + name = StripDoubleQuotes(name); + strcpy((*m)[i].name,name); + module = StripDoubleQuotes(module); + strcpy((*m)[i].module,module); + group = StripDoubleQuotes(group); + strcpy((*m)[i].group,group); +} + +void fill_ccs_matrix(ccs_matrix *m,int cc, int ccs, int scc, int ticks, int bytes, int h_o, int count, int i) +{ + heap_sample_matrix *hsm; + + if ((*m)[i].cc == 0) /* added for type 2 stack semantics, but should not */ + /* change behaviour of type 1 (apart from CAF:REP. */ + { + if (i>MAX_IDENTIFIERS) + { fprintf(logFile,"Cost centre stack MAX_IDENTIFIERS exceeded: %i \n",i); exit(1); } + hsm = (*m)[i].hsm; + (*m)[i].cc = cc; (*m)[i].ccs = ccs; + (*m)[i].ticks = ticks; (*m)[i].bytes = bytes; (*m)[i].scc = scc; + (*hsm)[h_o].count = count; + } + else fprintf(logFile,"Ignoring redeclaration of stack %i\n",i); +} + +void add_ccs_costs(ccs_matrix *m, int b,int c,int d,int x,int y,int h_o, int co) +{ + (*m)[c].scc = (*m)[c].scc + d; + (*m)[c].ticks = (*m)[c].ticks + x; + (*m)[c].bytes = (*m)[c].bytes + y; +} + +void add_heap_sample_costs(ccs_matrix *m, int b,int c,int d,int x,int y,int h_o, int co) +{ + heap_sample_matrix *hsm = (*m)[c].hsm; + if (((*hsm)[h_o].count)==-1) + (*hsm)[h_o].count = (*hsm)[h_o].count + co + 1; /* as init is -1 */ + else + (*hsm)[h_o].count = (*hsm)[h_o].count + co; +} + +void add_heap_object(heap_object_matrix *m, int pos, int t, char* des, int tr) +{ + if (pos>MAX_IDENTIFIERS) + { fprintf(logFile,"Heap object MAX_IDENTIFIERS exceeded: %i \n",pos); exit(1); } + (*m)[pos].type = t; + strcpy((*m)[pos].descriptor,des); + (*m)[pos].type_constr_ref = tr; +} + +void add_type_constr_object(type_constr_matrix *m, int pos, char* mod, char* n) +{ + if (pos>MAX_IDENTIFIERS) + { fprintf(logFile,"Type constructor MAX_IDENTIFIERS exceeded: %i \n",pos); exit(1); } + strcpy((*m)[pos].module,mod); + strcpy((*m)[pos].name,n); +} + + +// Printing routines + +void print_heap_update_list(heap_update_list *m, int number) +{ + int i; + fprintf(logFile,"["); + for (i=0; i<number;i++) + { + fprintf(logFile," (%i,%i,%i) ",(*m)[i].ccs,(*m)[i].ho,(*m)[i].count); + } + fprintf(logFile,"]\n"); +} + +void print_TheHeap(TheHeap *h) +{ + int i; + fprintf(logFile,"The Heap\n========\n"); + for (i=0; i<MAX_TIME;i++) + { + if ((*h)[i].no_samples>0) + { + fprintf(logFile,"Sample time %i, number of samples %i actual samples " + ,i,(*h)[i].no_samples); + print_heap_update_list((*h)[i].acc_samples,(*h)[i].no_samples); + } + } +} + +void PrintXaxis(FILE *HEAP_PROFILE, TheHeap *h) +{ + int i; + fprintf(HEAP_PROFILE," "); + for (i=0; i<MAX_TIME;i++) + { + if ((*h)[i].no_samples>0) + fprintf(HEAP_PROFILE,"%i ",i); + } +} + +int FindSample(heap_update_list *m, int number, int element) +{ + int i; + for (i=0; i<number;i++) + { + if ((*m)[i].ho==element) + return ((*m)[i].count); + } + return 0; +} + +void PrintSampleCosts(FILE *hfp, TheHeap *h, int element) +{ + int i; + int total = 0; + for (i=0; i<MAX_TIME;i++) + { + if ((*h)[i].no_samples>0) + { + total = total + FindSample((*h)[i].acc_samples,(*h)[i].no_samples,element); + fprintf(hfp," %i ",total); + } + } +} + +void print_cc_matrix(cc_matrix *m) +{ + int i; + char *blank="blank"; + fprintf(logFile,"Cost centre matrix\n"); + fprintf(logFile,"==================\n"); + for (i=0; i<MAX_IDENTIFIERS; i++) + { if (strcmp((*m)[i].name,blank)!=0) + fprintf(logFile,"%s %s %s\n",(*m)[i].name,(*m)[i].module,(*m)[i].group); } + fprintf(logFile,"\n"); +} + +void print_heap_object_matrix(FILE* hfp, TheHeap *h, heap_object_matrix *m) +{ + int i; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + if (((*m)[i].type)!=-1) + { + fprintf(hfp,"Y%i set {",i); + /* if ((*m)[i].type==1) fprintf(hfp,"data_contr "); + if ((*m)[i].type==2) fprintf(hfp,"PAP "); + if ((*m)[i].type==3) fprintf(hfp,"thunk "); + if ((*m)[i].type==4) fprintf(hfp,"function "); + if ((*m)[i].type==5) fprintf(hfp,"dictionary "); + if ((*m)[i].type==1) + fprintf(hfp,"%s %i ",(*m)[i].descriptor,(*m)[i].type_constr_ref); + else + fprintf(hfp,"%s ",(*m)[i].descriptor); */ + PrintSampleCosts(hfp,h,i); + fprintf(hfp,"}\n"); + } + } +} + +int number_of_heap_objects(heap_object_matrix *m) +{ + int i; + int count = 0; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + if (((*m)[i].type)!=-1) count++; + } + return count; +} + +void names_of_heap_objects(FILE *hfp, heap_object_matrix *m) +{ + int i; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + if (((*m)[i].type)!=-1) + fprintf(hfp,"Y%i ",i); + } + fprintf(hfp,"\n"); +} + +void names_and_colour_assignment(FILE *hfp, heap_object_matrix *m) +{ + int i; + int colour=0; + for (i=0; i<MAX_IDENTIFIERS; i++) + { + if (((*m)[i].type)!=-1) + { + switch(colour) + { + case 0 : fprintf(hfp,"%s \t Y%i \t red \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + case 1 : fprintf(hfp,"%s \t Y%i \t blue \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + case 2 : fprintf(hfp,"%s \t Y%i \t green \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + case 3 : fprintf(hfp,"%s \t Y%i \t yellow \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + case 4 : fprintf(hfp,"%s \t Y%i \t pink \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + case 5 : fprintf(hfp,"%s \t Y%i \t goldenrod \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + case 6 : fprintf(hfp,"%s \t Y%i \t orange \t fdiagonal1\n",(*m)[i].descriptor,i); + colour++; break; + default: fprintf(hfp,"%s \t Y%i \t purple \t fdiagonal1\n",(*m)[i].descriptor,i); + colour=0; break; + } + } + } +} + +void print_type_constr_matrix(type_constr_matrix *m) +{ + int i; + char *blank="blank"; + fprintf(logFile,"Type constructor matrix\n"); + fprintf(logFile,"=======================\n"); + for (i=0; i<MAX_IDENTIFIERS; i++) + { + if (strcmp((*m)[i].name,blank)!=0) + fprintf(logFile,"%i %s %s\n",i,(*m)[i].module,(*m)[i].name); + } +} + +void print_heap_sample_matrix(heap_sample_matrix *m) +{ + int i; + fprintf(logFile,"HeapSamples["); + for (i=0; i<MAX_IDENTIFIERS; i++) + { + if ((*m)[i].count!=-1) fprintf(logFile,"(%i,%i),",i,(*m)[i].count); + } + fprintf(logFile,"]\n"); +} + +void print_ccs_matrix(ccs_matrix *m) +{ + int i; + fprintf(logFile,"Cost centre stack matrix\n"); + fprintf(logFile,"========================\n"); + for (i=0; i<MAX_IDENTIFIERS; i++) + { if ((*m)[i].cc!=0) + { + fprintf(logFile,"%i %i %i %i %i \n",(*m)[i].cc,(*m)[i].ccs,(*m)[i].scc, + (*m)[i].ticks,(*m)[i].bytes); + } + } + fprintf(logFile,"\n"); +} + + +/* No longer used */ + +void FormStack(ccs_matrix *m, cc_matrix *n, int i, char s[]) +{ + int j = i; + if ((*m)[j].cc != 0) + { + strcat(s,(*n)[(*m)[j].cc].name); + strcat(s," "); + while ((*m)[j].ccs != (-1)) + { + strcat(s,(*n)[(*m)[(*m)[j].ccs].cc].name); + strcat(s,","); + j = (*m)[j].ccs; + } + } + else fprintf(logFile,"ERROR: Form Stack %i\n",i); +} + +/* This version, which is used, adds the module and group name to the cost centre name*/ +/* This means the cost centre name remains unique when it is textualised and fed into */ +/* daVinci. It also allows the module and group name to be extracted at the display */ +/* level */ + +void FormStack2(ccs_matrix *m, cc_matrix *n, int i, char s[]) +{ + int j = i; + if ((*m)[j].cc != 0) + { + strcat(s,(*n)[(*m)[j].cc].name); + strcat(s,"&"); + strcat(s,(*n)[(*m)[j].cc].module); + strcat(s,"&"); + strcat(s,(*n)[(*m)[j].cc].group); + strcat(s," "); + while ((*m)[j].ccs != (-1)) + { + strcat(s,(*n)[(*m)[(*m)[j].ccs].cc].name); + strcat(s,"&"); + strcat(s,(*n)[(*m)[(*m)[j].ccs].cc].module); + strcat(s,"&"); + strcat(s,(*n)[(*m)[(*m)[j].ccs].cc].group); + strcat(s,","); + j = (*m)[j].ccs; + } + } + else fprintf(logFile,"ERROR: Form Stack %i\n",i); +} + +void PrintStack(ccs_matrix *m, cc_matrix *n, int i) +{ + int j = i; + if ((*m)[j].cc != 0) + { + fprintf(logFile,"<"); + fprintf(logFile,"%s,",(*n)[(*m)[j].cc].name); + while ((*m)[j].ccs != (-1)) + { + fprintf(logFile,"%s,",(*n)[(*m)[(*m)[j].ccs].cc].name); + j = (*m)[j].ccs; + } + fprintf(logFile,"> "); + fprintf(logFile,"%i scc %i ticks %i bytes ", + (*m)[i].scc,(*m)[i].ticks,(*m)[i].bytes); + print_heap_sample_matrix((*m)[i].hsm); + } + else + { /* fprintf(logFile,"empty stack\n"); */ } +} + +int CountStacks(ccs_matrix *m) +{ + int j; + int count = 0; + for (j=0; j<MAX_IDENTIFIERS;j++) if ((*m)[j].cc != 0) count++; + return count; +} + +void PrintAllStacks(ccs_matrix *m, cc_matrix *n) +{ + int i; + fprintf(logFile,"Stacks\n======\n"); + for (i=0;i<MAX_IDENTIFIERS;i++) { PrintStack(m,n,i); } +} + + +/* ----------------------------------------------------------------------------- + * TCL Heap profile generator + * -------------------------------------------------------------------------- */ + +void produce_HEAP_PROFILE(FILE *HEAP_PROFILE, TheHeap *th, heap_object_matrix *ho_m) +{ + // First the header information + fprintf(HEAP_PROFILE,"#!/home/sj/blt2.4o/src/bltwish\n"); + fprintf(HEAP_PROFILE,"package require BLT\n"); + fprintf(HEAP_PROFILE,"if { $tcl_version >= 8.0 } {\n"); + fprintf(HEAP_PROFILE,"\t \t namespace import blt::*\n"); + fprintf(HEAP_PROFILE,"namespace import -force blt::tile::*\n"); + fprintf(HEAP_PROFILE,"}\n"); + fprintf(HEAP_PROFILE,"source scripts/demo.tcl\n"); + fprintf(HEAP_PROFILE,"proc FormatXTicks { w value } {\n"); + fprintf(HEAP_PROFILE,"\t \t set index [expr round($value)]\n"); + fprintf(HEAP_PROFILE,"\t \t if { $index != $value } {\n"); + fprintf(HEAP_PROFILE,"\t \t \t return $value\n"); + fprintf(HEAP_PROFILE,"\t \t}\n"); + fprintf(HEAP_PROFILE,"incr index -1\n"); + + // Now the code to generate the units in the X axis + + fprintf(HEAP_PROFILE,"set name [lindex { "); + PrintXaxis(HEAP_PROFILE,th); + fprintf(HEAP_PROFILE," } $index]\n"); + + fprintf(HEAP_PROFILE,"return $name\n"); + fprintf(HEAP_PROFILE,"}\n"); + + // more general graph stuff + + fprintf(HEAP_PROFILE,"source scripts/stipples.tcl\n"); + fprintf(HEAP_PROFILE,"image create photo bgTexture -file ./images/chalk.gif\n"); + fprintf(HEAP_PROFILE,"option add *Button.padX 5\n"); + fprintf(HEAP_PROFILE,"option add *tile bgTexture\n"); + fprintf(HEAP_PROFILE,"option add *Radiobutton.font -*-courier*-medium-r-*-*-14-*-*\n"); + fprintf(HEAP_PROFILE,"option add *Radiobutton.relief flat\n"); + fprintf(HEAP_PROFILE,"option add *Radiobutton.borderWidth 2\n"); + fprintf(HEAP_PROFILE,"option add *Radiobutton.highlightThickness 0\n"); + fprintf(HEAP_PROFILE,"option add *Htext.font -*-times*-bold-r-*-*-14-*-*\n"); + fprintf(HEAP_PROFILE,"option add *Htext.tileOffset no\n"); + fprintf(HEAP_PROFILE,"option add *header.font -*-times*-medium-r-*-*-14-*-*\n"); + fprintf(HEAP_PROFILE,"option add *Barchart.font -*-helvetica-bold-r-*-*-14-*-*\n"); + + fprintf(HEAP_PROFILE,"option add *Barchart.title \"Heap profile of program "); + // TO DO: Add program name in here + fprintf(HEAP_PROFILE,"\"\n"); + + fprintf(HEAP_PROFILE,"option add *Axis.tickFont -*-helvetica-medium-r-*-*-12-*-*\n"); + fprintf(HEAP_PROFILE,"option add *Axis.titleFont -*-helvetica-bold-r-*-*-12-*-*\n"); + fprintf(HEAP_PROFILE,"option add *x.Command FormatXTicks\n"); + fprintf(HEAP_PROFILE,"option add *x.Title \"Time (seconds)\"\n"); + fprintf(HEAP_PROFILE,"option add *y.Title \"Heap usage (000 bytes)\"\n"); + fprintf(HEAP_PROFILE,"option add *activeBar.Foreground pink\noption add *activeBar.stipple dot3\noption add *Element.Background red\noption add *Element.Relief raised\n"); + fprintf(HEAP_PROFILE,"option add *Grid.dashes { 2 4 }\noption add *Grid.hide no\noption add *Grid.mapX \"\"\n"); + fprintf(HEAP_PROFILE,"option add *Legend.Font \"-*-helvetica*-bold-r-*-*-12-*-*\"\noption add *Legend.activeBorderWidth 2\noption add *Legend.activeRelief raised \noption add *Legend.anchor ne \noption add *Legend.borderWidth 0\noption add *Legend.position right\n"); + fprintf(HEAP_PROFILE,"option add *TextMarker.Font *Helvetica-Bold-R*14*\n"); + fprintf(HEAP_PROFILE,"set visual [winfo screenvisual .] \nif { $visual != \"staticgray\" && $visual != \"grayscale\" } {\n option add *print.background yellow\n option add *quit.background red\n option add *quit.activeBackground red2\n}\n"); + fprintf(HEAP_PROFILE,"htext .title -text {\n Heap profile\n}\n"); + fprintf(HEAP_PROFILE,"htext .header -text {\n %%%% \n"); + fprintf(HEAP_PROFILE," radiobutton .header.stacked -text stacked -variable barMode \\\n -anchor w -value \"stacked\" -selectcolor red -command {\n .graph configure -barmode $barMode\n } \n .header append .header.stacked -width 1.5i -anchor w\n"); + fprintf(HEAP_PROFILE," %%%% Heap usage stacked: overall height is the sum of the heap used. \n %%%% \n"); + fprintf(HEAP_PROFILE," radiobutton .header.aligned -text aligned -variable barMode \\\n -anchor w -value \"aligned\" -selectcolor yellow -command {\n .graph configure -barmode $barMode }\n .header append .header.aligned -width 1.5i -fill x\n"); + fprintf(HEAP_PROFILE," %%%% Heap usage components displayed side-by-side.\n %%%%\n"); + fprintf(HEAP_PROFILE," radiobutton .header.overlap -text \"overlap\" -variable barMode \\\n -anchor w -value \"overlap\" -selectcolor green -command {\n .graph configure -barmode $barMode\n }\n .header append .header.overlap -width 1.5i -fill x\n"); + fprintf(HEAP_PROFILE," %%%% Heap usage shown as an overlapped histogram.\n %%%%\n"); + fprintf(HEAP_PROFILE," radiobutton .header.normal -text \"normal\" -variable barMode \\\n -anchor w -value \"normal\" -selectcolor blue -command {\n .graph configure -barmode $barMode\n }\n .header append .header.normal -width 1.5i -fill x\n"); + fprintf(HEAP_PROFILE," %%%% Heap components overlayed one on top of the next. \n}\n"); + fprintf(HEAP_PROFILE,"htext .footer -text { To create a postscript file \"heap_profile.ps\", press the %%%%\n button $htext(widget).print -text print -command {\n puts stderr [time {.graph postscript output heap_profile.ps}]\n }\n $htext(widget) append $htext(widget).print\n%%%% button.}\n"); + fprintf(HEAP_PROFILE,"barchart .graph -tile bgTexture\n"); + + // This is where the actual data comes in + + fprintf(HEAP_PROFILE,"vector X "); + names_of_heap_objects(HEAP_PROFILE,ho_m); + fprintf(HEAP_PROFILE,"\nX set { "); + PrintXaxis(HEAP_PROFILE,th); + fprintf(HEAP_PROFILE," }\n"); + + print_heap_object_matrix(HEAP_PROFILE,th, ho_m); + + // NAMES FOR THE ATTRIBUTES + fprintf(HEAP_PROFILE,"set attributes {\n"); + names_and_colour_assignment(HEAP_PROFILE,ho_m); + fprintf(HEAP_PROFILE,"}\n"); + + fprintf(HEAP_PROFILE,"foreach {label yData color stipple} $attributes {\n .graph element create $yData -label $label -bd 1 \\\n -ydata $yData -xdata X -fg ${color}3 -bg ${color}1 -stipple $stipple\n}\n"); + fprintf(HEAP_PROFILE,".header.stacked invoke\n"); + fprintf(HEAP_PROFILE,"scrollbar .xbar -command { .graph axis view x } -orient horizontal\nscrollbar .ybar -command { .graph axis view y } -orient vertical\n.graph axis configure x -scrollcommand { .xbar set } -logscale no -loose no\n.graph axis configure y -scrollcommand { .ybar set } -logscale no -loose no\n"); + fprintf(HEAP_PROFILE,"table . \\\n 0,0 .title -fill x \\\n 1,0 .header -fill x \\\n 2,0 .graph -fill both \\\n 3,0 .xbar -fill x \\\n 5,0 .footer -fill x\n"); + fprintf(HEAP_PROFILE,"table configure . r0 r1 r3 r4 r5 -resize none\n"); + fprintf(HEAP_PROFILE,"Blt_ZoomStack .graph\nBlt_Crosshairs .graph\nBlt_ActiveLegend .graph\nBlt_ClosestPoint .graph\n"); + fprintf(HEAP_PROFILE,".graph marker bind all <B2-Motion> {\n set coords [%%W invtransform %%x %%y]\n catch { %%W marker configure [%%W marker get current] -coords $coords }\n}\n.graph marker bind all <Enter> {\n set marker [%%W marker get current]\n catch { %%W marker configure $marker -bg green}\n}\n.graph marker bind all <Leave> {\n set marker [%%W marker get current]\n catch { %%W marker configure $marker -bg \"\"}\n}\n"); + +} + + +/* ----------------------------------------------------------------------------- + * Read and create the raw profile data structure + * -------------------------------------------------------------------------- */ + +/* void readRawProfile(FILE *fptr,int *nonodes) { */ + +void readRawProfile(FILE *fp,int *nonodes, int MaxNoNodes) { + char stack[MAX_PROFILE_LINE_LENGTH]; + int i,nolines,sstepline,syncs; + char *ptr,*drag; + + float comp_max, comp_avg, comp_min, /* SYNCS */ + comm_max, comm_avg, comm_min, /* COMP */ + comp_idle_max, comp_idle_avg, comp_idle_min; /* COMM */ + + /* Cost relationships are comp=scc, comm=ticks, comp_idle=bytes */ + + long int hmax,havg,hmin; /* COMPIDLE */ + + /* set to zero for now. Might use these later for heap costs. */ + + /* GHC specific variables */ + + int a,b,c,d,x,z,count, next; + int newloop; + char e[MAX_STRING_SIZE]; + char f[MAX_STRING_SIZE]; + char lline[MAX_PROFILE_LINE_LENGTH]; + + /* identifiers generated by the XML handler */ + char *ccentre=">>cost_centre"; + char *ccstack=">>cost_centre_stack"; + char *sccsample=">>scc_sample"; + char *heapsample=">>heap_sample"; + char *heapupdate=">>heap_update"; + char *heapobject=">>heap_object"; + char *typeconstr=">>type_constr"; + char *ending=">>"; + + /* FILE *fp; */ + + cc_matrix *cc_m; + ccs_matrix *ccs_m; + heap_object_matrix *ho_m; + type_constr_matrix *tc_m; + TheHeap *th; + + FILE *HEAP_PROFILE; + + HEAP_PROFILE = fopen("GHCbarchart.tcl", "w"); + if (HEAP_PROFILE == NULL){ + fprintf(stderr,"tcl script generator: ERROR- GHCbarchart.tcl cannot be created\a\n"); + exit(1); + } + + th = (p_TheHeap) malloc (sizeof(TheHeap)); + cc_m = (p_cc_matrix) malloc (sizeof(cc_matrix)); + //cc_m = (p_cc_matrix) calloc(MAX_IDENTIFIERS,sizeof(_cc_)); + ccs_m = (p_ccs_matrix) malloc (sizeof(ccs_matrix)); + ho_m = (p_heap_object_matrix) malloc (sizeof(heap_object_matrix)); + tc_m = (p_type_constr_matrix) malloc (sizeof(type_constr_matrix)); + + /* End of GHC specific variables */ + + //fprintf(logFile,"Number 1 %i \n",MAX_IDENTIFIERS*sizeof(_cc_)); + //fprintf(logFile,"Number 2 %i \n",sizeof(cc_matrix)); + + nolines=0; /* Number of lines read in from profile log file */ + + /* GHC specific */ + count = 0; + next = 0; + + initialise_cc_matrix(cc_m); + initialise_ccs_matrix(ccs_m); + initialise_heap_object_matrix(ho_m); + initialise_type_constr_matrix(tc_m); + initialise_TheHeap(th); + + fprintf(logFile,"MAX_IDENTIFIERS = %i \n",MAX_IDENTIFIERS); + + /* end GHC specific */ + + /* CAF fixing */ + fill_cc_matrix(cc_m,"CAF:REPOSITORY","PROFILER","PROFILER",MAX_IDENTIFIERS-1); + fill_ccs_matrix(ccs_m,MAX_IDENTIFIERS-1,1,0.0,0.0,0.0,0,-1,MAX_IDENTIFIERS-1); + + /* + + This builds a node in the graph called CAF:REPOSITORY, which can be + found off the root node. All CAFs are subsequently hung from this node + which means the node node can be hidden using the abstraction + mechanisms provided by daVinci. + + */ + + + /* This is the GHC file handler which reads the lines from the profile log file and */ + /* puts the stack and cost information in the raw profile data structure */ + + while (fscanf(fp,"%s",lline)) + { + /* Kill the end of the logfile with the ">>" string */ + if (strcmp(lline,ending)==0) break; + + /* Deal with the cost centres */ + if (strcmp(ccentre,lline)==0) + { + next = fgetc(fp); + //while (fscanf(fp," %i %[^ ] %[^ ] %s", &z, e, f, g)!=0) + while (fscanf(fp," %i %[^ ] %s", &z, e, f)!=0) + { + fprintf(logFile,"Declaring cost centre `%i %s %s %s' \n",z,e,f,f); + fflush(logFile); + fill_cc_matrix(cc_m,e,f,f,z); + next = fgetc(fp); + } + } + else + { + + /* Deal with the cost centre stacks */ + if (strcmp(ccstack,lline)==0) + { + next = fgetc(fp); + while (fscanf(fp,"%i %i %i",&a,&d,&b)!=0) + { + if (d==1) /* of size one */ + { + fprintf(logFile,"Declaring cost centre stack `%i %i %i'\n",a,d,b); + fill_ccs_matrix(ccs_m,b,-1,(*ccs_m)[a].scc,(*ccs_m)[a].ticks,(*ccs_m)[a].bytes,0,-1,a); + } + if (d==2) /* of size > 1 */ + { + fscanf(fp," %i",&c); + + /* CAF fixing */ + fprintf(logFile,"Declaring cost centre stack `%i %i %i %i'\n",a,d,b,c); + if ((c==1)&&!(strncmp((*cc_m)[b].name,"CAF",2))) + // fill_ccs_matrix(ccs_m,b,MAX_IDENTIFIERS-1,(*ccs_m)[a].scc,(*ccs_m)[a].ticks,(*ccs_m)[a].bytes,0,-1,a); + /* The line above hangs all CAFs off the CAF:REPOSITORY node + in the daVinci graph. For programs which have a small + number of CAFs this works nicely. However, when the + number of CAFs become very large (eg +200) then the + daVinci graph begins to look horid and, after (say) + +500 CAF nodes, becomes very slow to load. So to + fix this we replace the code with the line below. + */ + if (!(strncmp((*cc_m)[b].name,"CAF:main",7))) + /* Treat CAF:main as a normal node */ + fill_ccs_matrix(ccs_m,b,c,(*ccs_m)[a].scc,(*ccs_m)[a].ticks,(*ccs_m)[a].bytes,0,-1,a); + /* merge the rest */ + else + //add_ccs_costs(ccs_m,0,MAX_IDENTIFIERS-1,(*ccs_m)[a].scc,(*ccs_m)[a].ticks,(*ccs_m)[a].bytes,0,0); + fill_ccs_matrix(ccs_m,MAX_IDENTIFIERS-1,1,(*ccs_m)[a].scc,(*ccs_m)[a].ticks,(*ccs_m)[a].bytes,0,-1,a); + /* This does not even bother registering the new CAFs + as daVinci nodes, but instead just merges the CAF + with the CAF:REPOSITORY node. This greatly reduces + the number of CAFs daVinci has to deal with, though + may make the graph look a little different! + + Also note that now Simon has changed the semantics, + you will want to treat adding CAF nodes in a + different way to adding normal program nodes + */ + else + /* Normal mode */ + fill_ccs_matrix(ccs_m,b,c,(*ccs_m)[a].scc,(*ccs_m)[a].ticks,(*ccs_m)[a].bytes,0,-1,a); + } + next = fgetc(fp); + } + } + else + { + + /* Deal with the scc_samples */ + if (strcmp(sccsample,lline)==0) + { + next = fgetc(fp); + while (fscanf(fp,"%i %i %i %i",&a,&d,&b,&c)) + { + fprintf(logFile,"Loading scc_samples `%i %i %i %i'\n",a,d,b,c); + add_ccs_costs(ccs_m,0,a,d,b,c,0,0); + next = fgetc(fp); + } + } /* end sccsample if */ + else + { + + /* Deal with the heap samples */ + if (strcmp(heapsample,lline)==0) + { + next = fgetc(fp); + while (fscanf(fp,"%i %i %i",&a,&d,&b)) + { + fprintf(logFile,"Loading heap_samples `%i %i %i'\n",a,d,b); + add_heap_sample_costs(ccs_m,0,a,0,0,0,d,b); + next = fgetc(fp); + } + } /* end heapsample if */ + else + { + + /* Deal with the heap objects */ + if (strcmp(heapobject,lline)==0) + { + next = fgetc(fp); + while (fscanf(fp,"%i %i",&a,&d)) + { + if (d==1) + { + fscanf(fp," %s %i",e,&b); + add_heap_object(ho_m,a,d,e,b); + } + else + { + fscanf(fp," %s",e); + add_heap_object(ho_m,a,d,e,-1); + } + next = fgetc(fp); + } + } /* end heapobject if */ + else + { + + /* Deal with the type constructors */ + if (strcmp(typeconstr,lline)==0) + { + next = fgetc(fp); + while (fscanf(fp,"%i %s %s",&a,e,f)) + { + add_type_constr_object(tc_m,a,e,f); + next = fgetc(fp); + } + } /* end type constructor if */ + else + { + + /* Deal with the heap_updates */ + if (strcmp(heapupdate,lline)==0) + { + next = fgetc(fp); + while (fscanf(fp,"%i %i %i %i %i %i",&a,&d,&b,&c,&z,&x)) + { + add_to_TheHeap(th,a,b,c,z); + fprintf(logFile,"Adding heap sample %i %i %i %i\n",a,b,c,z); + while (x) /* more than one sample */ + { + fscanf(fp," %i %i %i %i",&b,&c,&z,&x); + add_to_TheHeap(th,a,b,c,z); + fprintf(logFile,"Adding heap sample %i %i %i %i\n",a,b,c,z); + } + next = fgetc(fp); + } + + } /* end heap update if */ + + } /* end type constructor else */ + + } /* end heapobject else */ + + } /* end heapsample else */ + } /* end sccsample else */ + } /* end ccstack else */ + } /* end ccstack if */ + } /* end while */ + + print_cc_matrix(cc_m); + print_ccs_matrix(ccs_m); + fprintf(logFile,"There are %i stacks\n",CountStacks(ccs_m)); + print_type_constr_matrix(tc_m); + + /* Functions for heap profile */ + print_TheHeap(th); + fprintf(logFile,"The units for the x axis are \n"); + PrintXaxis(logFile,th); + fprintf(logFile,"\n"); + fprintf(logFile,"There are %i distinct heap objects\n",number_of_heap_objects(ho_m)); + names_of_heap_objects(logFile,ho_m); + names_and_colour_assignment(logFile,ho_m); + print_heap_object_matrix(logFile,th,ho_m); + + PrintAllStacks(ccs_m,cc_m); + /* comment out line below to remove the heap profile generator */ + produce_HEAP_PROFILE(HEAP_PROFILE,th,ho_m); + fclose(HEAP_PROFILE); + + /* End of GHC file handler */ + + + /* Now process the stack matrix */ + + for (newloop=0;newloop<MAX_IDENTIFIERS;newloop++) + { if ((*ccs_m)[newloop].cc != 0) + { + + sstepline = 0; + FormStack2(ccs_m,cc_m,newloop,stack); + + syncs = 0; + comp_max = (float)(*ccs_m)[newloop].scc; + comp_avg = (float)(*ccs_m)[newloop].scc; + comp_min = (float)(*ccs_m)[newloop].scc; + comm_max = (float)(*ccs_m)[newloop].ticks; + comm_avg = (float)(*ccs_m)[newloop].ticks; + comm_min = (float)(*ccs_m)[newloop].ticks; + comp_idle_max = (float)(*ccs_m)[newloop].bytes; + comp_idle_avg = (float)(*ccs_m)[newloop].bytes; + comp_idle_min = (float)(*ccs_m)[newloop].bytes; + hmax = 0.0; havg = 0.0; hmin = 0.0; + + /* Dynamic memory allocation for raw_profile data structure */ + + if (raw_profile_next==raw_profile_size) enlargeRawProfile(); + + /* Assign data from single logfile entry to raw_profile data structure */ + /* this deals with the cost metrics */ + + raw_profile[raw_profile_next].active = 1; + raw_profile[raw_profile_next].cost.syncs = syncs; + raw_profile[raw_profile_next].cost.comp_max = comp_max; + raw_profile[raw_profile_next].cost.comp_avg = comp_avg; + raw_profile[raw_profile_next].cost.comp_min = comp_min; + raw_profile[raw_profile_next].cost.comm_max = comm_max; + raw_profile[raw_profile_next].cost.comm_avg = comm_avg; + raw_profile[raw_profile_next].cost.comm_min = comm_min; + raw_profile[raw_profile_next].cost.comp_idle_max= comp_idle_max; + raw_profile[raw_profile_next].cost.comp_idle_avg= comp_idle_avg; + raw_profile[raw_profile_next].cost.comp_idle_min= comp_idle_min; + raw_profile[raw_profile_next].cost.hrel_max = hmax; + raw_profile[raw_profile_next].cost.hrel_avg = havg; + raw_profile[raw_profile_next].cost.hrel_min = hmin; + + /* this deals with the stack itself */ + + raw_profile[raw_profile_next].stack=calloc(MAX_STACK_DEPTH, + sizeof(int)); + if (raw_profile[raw_profile_next].stack==NULL) { + fprintf(stderr,"{readRawProfile} unable to allocate stack entry"); + exit(1); + } + + fprintf(logFile,"STACK=\"%s\"\n",stack); + raw_profile[raw_profile_next].stack_size=1; + /* move the stack read frame to the first space (or comma) in the stack string */ + for(ptr=stack; ((*ptr)!=' ') && (*ptr!=',');ptr++) {} + fprintf(logFile,"TOS=%d at line %d\n",*ptr,sstepline); + + /* to distinguish the head of the stack from the rest */ + /* if read frame points to space you are at the head of the stack */ + if (*ptr==' ') + /* raw_profile[raw_profile_next].stack[0] + =lookupSymbolTable(CG_SSTEP,sstepline,(*ptr='\0',stack)); */ + /* This line has changed as GHC treats its cost-centres in a different */ + /* way to BSP. There is no distinction between 'a cost centre at line x' */ + /* and a normal cost centre. The fix is easy, just treat all cost centres, */ + /* even those at the head of the stack in the same way. */ + raw_profile[raw_profile_next].stack[0] + =lookupSymbolTable(CG_STACK,sstepline,(*ptr='\0',stack)); + else + /* otherwise you are looking at just another stack element */ + raw_profile[raw_profile_next].stack[0] + =lookupSymbolTable(CG_STACK,sstepline,(*ptr='\0',stack)); + + ptr++; /* move the read frame on one */ + drag=ptr; + for(;*ptr;ptr++) { /* find the next element in the stack */ + if (*ptr==',') { + *ptr='\0'; + if (Verbose) fprintf(logFile,"NAME=\"%s\"\n",drag); /* name of the next element */ + if (!ignore_function(drag)) { + raw_profile[raw_profile_next].stack[ + raw_profile[raw_profile_next].stack_size++] + = lookupSymbolTable(CG_STACK,0,drag); /* add element to the raw_profile */ + } + drag = ptr+1; + } + } + + /* create cost object */ + + raw_profile[raw_profile_next].cost.proc + =calloc(bsp_p,sizeof(object_cost_proc)); + if (raw_profile[raw_profile_next].cost.proc==NULL) { + fprintf(stderr,"Unable to allocate storage"); + exit(0); + } + + /* process the HREL information - one set for every BSP process */ + + for(i=0;i<bsp_p;i++) { + + raw_profile[raw_profile_next].cost.proc[i].proc_comp = 0.0; + raw_profile[raw_profile_next].cost.proc[i].proc_comm = 0.0; + raw_profile[raw_profile_next].cost.proc[i].proc_comp_idle= 0.0; + raw_profile[raw_profile_next].cost.proc[i].proc_hrel_in = 0; + raw_profile[raw_profile_next].cost.proc[i].proc_hrel_out = 0; + + } + + raw_profile_next++; /* Increase the raw profile data structure counter */ + nolines++; /* Increase the number of lines read */ + + strcpy(stack,""); /* reset the stack */ + } /* end of new if statement */ + } /* end of new for loop */ + + *nonodes = symbol_table_next; + fprintf(logFile,"%s: read %d lines from profile.Graph contains %i nodes.\n", + Pgm,nolines,symbol_table_next); + + free_cc_matrix(cc_m); /* be nice and clean up the cost centre matrix */ +} + +/* ----------------------------------------------------------------------------- + * Pretty print the raw profile data + * -------------------------------------------------------------------------- */ + +void printRawProfile() { + int i,j; + object_cost *cost; + int *stack; + + fprintf(logFile,"\n\nRAW DATA:\n"); + for(i=0;i<raw_profile_next;i++) { + cost = &raw_profile[i].cost; + stack = raw_profile[i].stack; + fprintf(logFile,"Stack=["); + for(j=0;j<raw_profile[i].stack_size;j++) + printSymbolTable_entry(stack[j]); + fprintf(logFile,"] %d Syncs %f Comp %f Comm %f Wait\n\n", + cost->syncs,cost->comp_max,cost->comm_max,cost->comp_idle_max); + } +} + +/* ----------------------------------------------------------------------------- + * Create connectivity matrix + * -------------------------------------------------------------------------- */ + +void createConnectivityMatrix(int NoNodes,Matrix *graph, + Matrix *costs,int *root, int inherit) { + object_cost zero_cost,*update; + int i,j,this,next; + + + zero_cost.comp_max =0.0; + zero_cost.comp_avg =0.0; + zero_cost.comp_min =0.0; + zero_cost.comm_max =0.0; + zero_cost.comm_avg =0.0; + zero_cost.comm_min =0.0; + zero_cost.comp_idle_max=0.0; + zero_cost.comp_idle_avg=0.0; + zero_cost.comp_idle_min=0.0; + zero_cost.hrel_max =0; + zero_cost.hrel_avg =0; + zero_cost.hrel_min =0; + zero_cost.syncs=0; + zero_cost.proc = NULL; + *graph = newMat(NoNodes,NoNodes,sizeof(int),(i=0,&i)); + *costs = newMat(NoNodes,1,sizeof(object_cost),&zero_cost); + for(i=0;i<NoNodes;i++) { + update=&Mat(object_cost,*costs,i,0); + update->proc=calloc(bsp_p,sizeof(object_cost_proc)); + if (update->proc==NULL){ + fprintf(stderr,"Unable to allocate storage"); + exit(0); + } + for(j=0;j<bsp_p;j++) { + update->proc[j].proc_comp =0.0; + update->proc[j].proc_comm =0.0; + update->proc[j].proc_comp_idle =0.0; + update->proc[j].proc_hrel_in =0; + update->proc[j].proc_hrel_out =0; + } + } + + for(i=0;i<raw_profile_next;i++) { + if (raw_profile[i].active) { + this = raw_profile[i].stack[0]; + next = this; + Mat(int,*graph,this,next) = 1; + update = &Mat(object_cost,*costs,next,0); + add_costs(update,raw_profile[i].cost); + for(j=1;j<raw_profile[i].stack_size;j++) { + this = next; + next = raw_profile[i].stack[j]; + Mat(int,*graph,next,this)=1; + update = &Mat(object_cost,*costs,next,0); + /* include this line for INHERITANCE; remove it for not! */ + if (inherit) add_costs(update,raw_profile[i].cost); + } + } + } + *root = raw_profile[0].stack[raw_profile[0].stack_size-1]; + + /* Check graph isn't empty */ + if (!Mat_dense(*costs,*root,0)) *root=-1; +} + +void printConnectivityMatrix(Matrix graph,Matrix costs,int root) { + int i,j; + object_cost cost; + + fprintf(logFile,"Root node is %d\n",root); + for(i=0;i<graph.rows;i++) { + fprintf(logFile,"%4d)",i); + printSymbolTable_entry(i); + cost = Mat(object_cost,costs,i,0); + fprintf(logFile,"%d %f %f %f\n\tBranch=[", + cost.syncs,cost.comp_max,cost.comm_max,cost.comp_idle_max); + for(j=0;j<graph.cols;j++) + if (Mat_dense(graph,i,j)) fprintf(logFile,"%d ",j); + fprintf(logFile,"]\n\n"); + } +} |