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sim-outorder.c
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sim-outorder.c
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/* sim-outorder.c - sample out-of-order issue perf simulator implementation */
/* SimpleScalar(TM) Tool Suite
* Copyright (C) 1994-2003 by Todd M. Austin, Ph.D. and SimpleScalar, LLC.
* All Rights Reserved.
*
* THIS IS A LEGAL DOCUMENT, BY USING SIMPLESCALAR,
* YOU ARE AGREEING TO THESE TERMS AND CONDITIONS.
*
* No portion of this work may be used by any commercial entity, or for any
* commercial purpose, without the prior, written permission of SimpleScalar,
* LLC (info@simplescalar.com). Nonprofit and noncommercial use is permitted
* as described below.
*
* 1. SimpleScalar is provided AS IS, with no warranty of any kind, express
* or implied. The user of the program accepts full responsibility for the
* application of the program and the use of any results.
*
* 2. Nonprofit and noncommercial use is encouraged. SimpleScalar may be
* downloaded, compiled, executed, copied, and modified solely for nonprofit,
* educational, noncommercial research, and noncommercial scholarship
* purposes provided that this notice in its entirety accompanies all copies.
* Copies of the modified software can be delivered to persons who use it
* solely for nonprofit, educational, noncommercial research, and
* noncommercial scholarship purposes provided that this notice in its
* entirety accompanies all copies.
*
* 3. ALL COMMERCIAL USE, AND ALL USE BY FOR PROFIT ENTITIES, IS EXPRESSLY
* PROHIBITED WITHOUT A LICENSE FROM SIMPLESCALAR, LLC (info@simplescalar.com).
*
* 4. No nonprofit user may place any restrictions on the use of this software,
* including as modified by the user, by any other authorized user.
*
* 5. Noncommercial and nonprofit users may distribute copies of SimpleScalar
* in compiled or executable form as set forth in Section 2, provided that
* either: (A) it is accompanied by the corresponding machine-readable source
* code, or (B) it is accompanied by a written offer, with no time limit, to
* give anyone a machine-readable copy of the corresponding source code in
* return for reimbursement of the cost of distribution. This written offer
* must permit verbatim duplication by anyone, or (C) it is distributed by
* someone who received only the executable form, and is accompanied by a
* copy of the written offer of source code.
*
* 6. SimpleScalar was developed by Todd M. Austin, Ph.D. The tool suite is
* currently maintained by SimpleScalar LLC (info@simplescalar.com). US Mail:
* 2395 Timbercrest Court, Ann Arbor, MI 48105.
*
* Copyright (C) 1994-2003 by Todd M. Austin, Ph.D. and SimpleScalar, LLC.
*/
#include <stdio.h>
#include <stdlib.h>
#include <math.h>
#include <assert.h>
#include <signal.h>
#include "host.h"
#include "misc.h"
#include "machine.h"
#include "regs.h"
#include "memory.h"
#include "cache.h"
#include "loader.h"
#include "syscall.h"
#include "bpred.h"
#include "resource.h"
#include "bitmap.h"
#include "options.h"
#include "eval.h"
#include "stats.h"
#include "ptrace.h"
#include "dlite.h"
#include "sim.h"
/* added for Wattch */
#include "power.h"
/*
* This file implements a very detailed out-of-order issue superscalar
* processor with a two-level memory system and speculative execution support.
* This simulator is a performance simulator, tracking the latency of all
* pipeline operations.
*/
/* simulated registers */
static struct regs_t regs;
/* simulated memory */
static struct mem_t *mem = NULL;
/*
* simulator options
*/
/* maximum number of inst's to execute */
static unsigned int max_insts;
/* number of insts skipped before timing starts */
static int fastfwd_count;
/* pipeline trace range and output filename */
static int ptrace_nelt = 0;
static char *ptrace_opts[2];
/* instruction fetch queue size (in insts) */
static int ruu_ifq_size;
/* extra branch mis-prediction latency */
static int ruu_branch_penalty;
/* speed of front-end of machine relative to execution core */
static int fetch_speed;
/* branch predictor type {nottaken|taken|perfect|bimod|2lev} */
static char *pred_type;
/* bimodal predictor config (<table_size>) */
static int bimod_nelt = 1;
int bimod_config[1] =
{ /* bimod tbl size */2048 };
/* 2-level predictor config (<l1size> <l2size> <hist_size> <xor>) */
static int twolev_nelt = 4;
int twolev_config[4] =
{ /* l1size */1, /* l2size */1024, /* hist */8, /* xor */FALSE};
/* combining predictor config (<meta_table_size> */
static int comb_nelt = 1;
int comb_config[1] =
{ /* meta_table_size */1024 };
/* return address stack (RAS) size */
int ras_size = 8;
/* BTB predictor config (<num_sets> <associativity>) */
static int btb_nelt = 2;
int btb_config[2] =
{ /* nsets */512, /* assoc */4 };
/* instruction decode B/W (insts/cycle) */
int ruu_decode_width;
/* instruction issue B/W (insts/cycle) */
int ruu_issue_width;
/* run pipeline with in-order issue */
static int ruu_inorder_issue;
/* issue instructions down wrong execution paths */
static int ruu_include_spec = TRUE;
/* instruction commit B/W (insts/cycle) */
int ruu_commit_width;
/* register update unit (RUU) size */
int RUU_size = 8;
/* load/store queue (LSQ) size */
int LSQ_size = 4;
/* l1 data cache config, i.e., {<config>|none} */
static char *cache_dl1_opt;
/* l1 data cache hit latency (in cycles) */
static int cache_dl1_lat;
/* l2 data cache config, i.e., {<config>|none} */
static char *cache_dl2_opt;
/* l2 data cache hit latency (in cycles) */
static int cache_dl2_lat;
/* l1 instruction cache config, i.e., {<config>|dl1|dl2|none} */
static char *cache_il1_opt;
/* l1 instruction cache hit latency (in cycles) */
static int cache_il1_lat;
/* l2 instruction cache config, i.e., {<config>|dl1|dl2|none} */
static char *cache_il2_opt;
/* l2 instruction cache hit latency (in cycles) */
static int cache_il2_lat;
/* flush caches on system calls */
static int flush_on_syscalls;
/* convert 64-bit inst addresses to 32-bit inst equivalents */
static int compress_icache_addrs;
/* memory access latency (<first_chunk> <inter_chunk>) */
static int mem_nelt = 2;
static int mem_lat[2] =
{ /* lat to first chunk */18, /* lat between remaining chunks */2 };
/* memory access bus width (in bytes) */
static int mem_bus_width;
/* instruction TLB config, i.e., {<config>|none} */
static char *itlb_opt;
/* data TLB config, i.e., {<config>|none} */
static char *dtlb_opt;
/* inst/data TLB miss latency (in cycles) */
static int tlb_miss_lat;
/* total number of integer ALU's available */
int res_ialu;
/* total number of integer multiplier/dividers available */
static int res_imult;
/* total number of memory system ports available (to CPU) */
int res_memport;
/* total number of floating point ALU's available */
int res_fpalu;
/* total number of floating point multiplier/dividers available */
static int res_fpmult;
/* options for Wattch */
int data_width = 64;
/* static power model results */
extern power_result_type power;
/* counters added for Wattch */
counter_t rename_access=0;
counter_t bpred_access=0;
counter_t window_access=0;
counter_t lsq_access=0;
counter_t regfile_access=0;
counter_t icache_access=0;
counter_t dcache_access=0;
counter_t dcache2_access=0;
counter_t alu_access=0;
counter_t ialu_access=0;
counter_t falu_access=0;
counter_t resultbus_access=0;
counter_t window_preg_access=0;
counter_t window_selection_access=0;
counter_t window_wakeup_access=0;
counter_t lsq_store_data_access=0;
counter_t lsq_load_data_access=0;
counter_t lsq_preg_access=0;
counter_t lsq_wakeup_access=0;
counter_t window_total_pop_count_cycle=0;
counter_t window_num_pop_count_cycle=0;
counter_t lsq_total_pop_count_cycle=0;
counter_t lsq_num_pop_count_cycle=0;
counter_t regfile_total_pop_count_cycle=0;
counter_t regfile_num_pop_count_cycle=0;
counter_t resultbus_total_pop_count_cycle=0;
counter_t resultbus_num_pop_count_cycle=0;
/* text-based stat profiles */
#define MAX_PCSTAT_VARS 8
static int pcstat_nelt = 0;
static char *pcstat_vars[MAX_PCSTAT_VARS];
/* convert 64-bit inst text addresses to 32-bit inst equivalents */
#ifdef TARGET_PISA
#define IACOMPRESS(A) \
(compress_icache_addrs ? ((((A) - ld_text_base) >> 1) + ld_text_base) : (A))
#define ISCOMPRESS(SZ) \
(compress_icache_addrs ? ((SZ) >> 1) : (SZ))
#else /* !TARGET_PISA */
#define IACOMPRESS(A) (A)
#define ISCOMPRESS(SZ) (SZ)
#endif /* TARGET_PISA */
/* operate in backward-compatible bugs mode (for testing only) */
static int bugcompat_mode;
/*
* functional unit resource configuration
*/
/* resource pool indices, NOTE: update these if you change FU_CONFIG */
#define FU_IALU_INDEX 0
#define FU_IMULT_INDEX 1
#define FU_MEMPORT_INDEX 2
#define FU_FPALU_INDEX 3
#define FU_FPMULT_INDEX 4
/* resource pool definition, NOTE: update FU_*_INDEX defs if you change this */
struct res_desc fu_config[] = {
{
"integer-ALU",
4,
0,
{
{ IntALU, 1, 1 }
}
},
{
"integer-MULT/DIV",
1,
0,
{
{ IntMULT, 3, 1 },
{ IntDIV, 20, 19 }
}
},
{
"memory-port",
2,
0,
{
{ RdPort, 1, 1 },
{ WrPort, 1, 1 }
}
},
{
"FP-adder",
4,
0,
{
{ FloatADD, 2, 1 },
{ FloatCMP, 2, 1 },
{ FloatCVT, 2, 1 }
}
},
{
"FP-MULT/DIV",
1,
0,
{
{ FloatMULT, 4, 1 },
{ FloatDIV, 12, 12 },
{ FloatSQRT, 24, 24 }
}
},
};
/*
* simulator stats
*/
/* SLIP variable */
static counter_t sim_slip = 0;
/* total number of instructions executed */
static counter_t sim_total_insn = 0;
/* total number of memory references committed */
static counter_t sim_num_refs = 0;
/* total number of memory references executed */
static counter_t sim_total_refs = 0;
/* total number of loads committed */
static counter_t sim_num_loads = 0;
/* total number of loads executed */
static counter_t sim_total_loads = 0;
/* total number of branches committed */
static counter_t sim_num_branches = 0;
/* total number of branches executed */
static counter_t sim_total_branches = 0;
/* cycle counter */
static tick_t sim_cycle = 0;
/* occupancy counters */
static counter_t IFQ_count; /* cumulative IFQ occupancy */
static counter_t IFQ_fcount; /* cumulative IFQ full count */
static counter_t RUU_count; /* cumulative RUU occupancy */
static counter_t RUU_fcount; /* cumulative RUU full count */
static counter_t LSQ_count; /* cumulative LSQ occupancy */
static counter_t LSQ_fcount; /* cumulative LSQ full count */
/* total non-speculative bogus addresses seen (debug var) */
static counter_t sim_invalid_addrs;
/*
* simulator state variables
*/
/* instruction sequence counter, used to assign unique id's to insts */
static unsigned int inst_seq = 0;
/* pipetrace instruction sequence counter */
static unsigned int ptrace_seq = 0;
/* speculation mode, non-zero when mis-speculating, i.e., executing
instructions down the wrong path, thus state recovery will eventually have
to occur that resets processor register and memory state back to the last
precise state */
static int spec_mode = FALSE;
/* cycles until fetch issue resumes */
static unsigned ruu_fetch_issue_delay = 0;
/* perfect prediction enabled */
static int pred_perfect = FALSE;
/* speculative bpred-update enabled */
static char *bpred_spec_opt;
static enum { spec_ID, spec_WB, spec_CT } bpred_spec_update;
/* level 1 instruction cache, entry level instruction cache */
struct cache_t *cache_il1;
/* level 1 instruction cache */
static struct cache_t *cache_il2;
/* level 1 data cache, entry level data cache */
struct cache_t *cache_dl1;
/* level 2 data cache */
struct cache_t *cache_dl2;
/* instruction TLB */
struct cache_t *itlb;
/* data TLB */
struct cache_t *dtlb;
/* branch predictor */
static struct bpred_t *pred;
/* functional unit resource pool */
static struct res_pool *fu_pool = NULL;
/* text-based stat profiles */
static struct stat_stat_t *pcstat_stats[MAX_PCSTAT_VARS];
static counter_t pcstat_lastvals[MAX_PCSTAT_VARS];
static struct stat_stat_t *pcstat_sdists[MAX_PCSTAT_VARS];
/* wedge all stat values into a counter_t */
#define STATVAL(STAT) \
((STAT)->sc == sc_int \
? (counter_t)*((STAT)->variant.for_int.var) \
: ((STAT)->sc == sc_uint \
? (counter_t)*((STAT)->variant.for_uint.var) \
: ((STAT)->sc == sc_counter \
? *((STAT)->variant.for_counter.var) \
: (panic("bad stat class"), 0))))
/* memory access latency, assumed to not cross a page boundary */
static unsigned int /* total latency of access */
mem_access_latency(int blk_sz) /* block size accessed */
{
int chunks = (blk_sz + (mem_bus_width - 1)) / mem_bus_width;
assert(chunks > 0);
return (/* first chunk latency */mem_lat[0] +
(/* remainder chunk latency */mem_lat[1] * (chunks - 1)));
}
/*
* cache miss handlers
*/
/* l1 data cache l1 block miss handler function */
static unsigned int /* latency of block access */
dl1_access_fn(enum mem_cmd cmd, /* access cmd, Read or Write */
md_addr_t baddr, /* block address to access */
int bsize, /* size of block to access */
struct cache_blk_t *blk, /* ptr to block in upper level */
tick_t now) /* time of access */
{
unsigned int lat;
if (cache_dl2)
{
/* access next level of data cache hierarchy */
lat = cache_access(cache_dl2, cmd, baddr, NULL, bsize,
/* now */now, /* pudata */NULL, /* repl addr */NULL);
/* Wattch -- Dcache2 access */
dcache2_access++;
if (cmd == Read)
return lat;
else
{
/* FIXME: unlimited write buffers */
return 0;
}
}
else
{
/* access main memory */
if (cmd == Read)
return mem_access_latency(bsize);
else
{
/* FIXME: unlimited write buffers */
return 0;
}
}
}
/* l2 data cache block miss handler function */
static unsigned int /* latency of block access */
dl2_access_fn(enum mem_cmd cmd, /* access cmd, Read or Write */
md_addr_t baddr, /* block address to access */
int bsize, /* size of block to access */
struct cache_blk_t *blk, /* ptr to block in upper level */
tick_t now) /* time of access */
{
/* Wattch -- main memory access -- Wattch-FIXME (offchip) */
/* this is a miss to the lowest level, so access main memory */
if (cmd == Read)
return mem_access_latency(bsize);
else
{
/* FIXME: unlimited write buffers */
return 0;
}
}
/* l1 inst cache l1 block miss handler function */
static unsigned int /* latency of block access */
il1_access_fn(enum mem_cmd cmd, /* access cmd, Read or Write */
md_addr_t baddr, /* block address to access */
int bsize, /* size of block to access */
struct cache_blk_t *blk, /* ptr to block in upper level */
tick_t now) /* time of access */
{
unsigned int lat;
if (cache_il2)
{
/* access next level of inst cache hierarchy */
lat = cache_access(cache_il2, cmd, baddr, NULL, bsize,
/* now */now, /* pudata */NULL, /* repl addr */NULL);
/* Wattch -- Dcache2 access */
dcache2_access++;
if (cmd == Read)
return lat;
else
panic("writes to instruction memory not supported");
}
else
{
/* access main memory */
if (cmd == Read)
return mem_access_latency(bsize);
else
panic("writes to instruction memory not supported");
}
}
/* l2 inst cache block miss handler function */
static unsigned int /* latency of block access */
il2_access_fn(enum mem_cmd cmd, /* access cmd, Read or Write */
md_addr_t baddr, /* block address to access */
int bsize, /* size of block to access */
struct cache_blk_t *blk, /* ptr to block in upper level */
tick_t now) /* time of access */
{
/* Wattch -- main memory access -- Wattch-FIXME (offchip) */
/* this is a miss to the lowest level, so access main memory */
if (cmd == Read)
return mem_access_latency(bsize);
else
panic("writes to instruction memory not supported");
}
/*
* TLB miss handlers
*/
/* inst cache block miss handler function */
static unsigned int /* latency of block access */
itlb_access_fn(enum mem_cmd cmd, /* access cmd, Read or Write */
md_addr_t baddr, /* block address to access */
int bsize, /* size of block to access */
struct cache_blk_t *blk, /* ptr to block in upper level */
tick_t now) /* time of access */
{
md_addr_t *phy_page_ptr = (md_addr_t *)blk->user_data;
/* no real memory access, however, should have user data space attached */
assert(phy_page_ptr);
/* fake translation, for now... */
*phy_page_ptr = 0;
/* return tlb miss latency */
return tlb_miss_lat;
}
/* data cache block miss handler function */
static unsigned int /* latency of block access */
dtlb_access_fn(enum mem_cmd cmd, /* access cmd, Read or Write */
md_addr_t baddr, /* block address to access */
int bsize, /* size of block to access */
struct cache_blk_t *blk, /* ptr to block in upper level */
tick_t now) /* time of access */
{
md_addr_t *phy_page_ptr = (md_addr_t *)blk->user_data;
/* no real memory access, however, should have user data space attached */
assert(phy_page_ptr);
/* fake translation, for now... */
*phy_page_ptr = 0;
/* return tlb miss latency */
return tlb_miss_lat;
}
/* register simulator-specific options */
void
sim_reg_options(struct opt_odb_t *odb)
{
opt_reg_header(odb,
"sim-outorder: This simulator implements a very detailed out-of-order issue\n"
"superscalar processor with a two-level memory system and speculative\n"
"execution support. This simulator is a performance simulator, tracking the\n"
"latency of all pipeline operations.\n"
);
/* instruction limit */
opt_reg_uint(odb, "-max:inst", "maximum number of inst's to execute",
&max_insts, /* default */0,
/* print */TRUE, /* format */NULL);
/* trace options */
opt_reg_int(odb, "-fastfwd", "number of insts skipped before timing starts",
&fastfwd_count, /* default */0,
/* print */TRUE, /* format */NULL);
opt_reg_string_list(odb, "-ptrace",
"generate pipetrace, i.e., <fname|stdout|stderr> <range>",
ptrace_opts, /* arr_sz */2, &ptrace_nelt, /* default */NULL,
/* !print */FALSE, /* format */NULL, /* !accrue */FALSE);
opt_reg_note(odb,
" Pipetrace range arguments are formatted as follows:\n"
"\n"
" {{@|#}<start>}:{{@|#|+}<end>}\n"
"\n"
" Both ends of the range are optional, if neither are specified, the entire\n"
" execution is traced. Ranges that start with a `@' designate an address\n"
" range to be traced, those that start with an `#' designate a cycle count\n"
" range. All other range values represent an instruction count range. The\n"
" second argument, if specified with a `+', indicates a value relative\n"
" to the first argument, e.g., 1000:+100 == 1000:1100. Program symbols may\n"
" be used in all contexts.\n"
"\n"
" Examples: -ptrace FOO.trc #0:#1000\n"
" -ptrace BAR.trc @2000:\n"
" -ptrace BLAH.trc :1500\n"
" -ptrace UXXE.trc :\n"
" -ptrace FOOBAR.trc @main:+278\n"
);
/* ifetch options */
opt_reg_int(odb, "-fetch:ifqsize", "instruction fetch queue size (in insts)",
&ruu_ifq_size, /* default */4,
/* print */TRUE, /* format */NULL);
opt_reg_int(odb, "-fetch:mplat", "extra branch mis-prediction latency",
&ruu_branch_penalty, /* default */3,
/* print */TRUE, /* format */NULL);
opt_reg_int(odb, "-fetch:speed",
"speed of front-end of machine relative to execution core",
&fetch_speed, /* default */1,
/* print */TRUE, /* format */NULL);
/* branch predictor options */
opt_reg_note(odb,
" Branch predictor configuration examples for 2-level predictor:\n"
" Configurations: N, M, W, X\n"
" N # entries in first level (# of shift register(s))\n"
" W width of shift register(s)\n"
" M # entries in 2nd level (# of counters, or other FSM)\n"
" X (yes-1/no-0) xor history and address for 2nd level index\n"
" Sample predictors:\n"
" GAg : 1, W, 2^W, 0\n"
" GAp : 1, W, M (M > 2^W), 0\n"
" PAg : N, W, 2^W, 0\n"
" PAp : N, W, M (M == 2^(N+W)), 0\n"
" gshare : 1, W, 2^W, 1\n"
" Predictor `comb' combines a bimodal and a 2-level predictor.\n"
);
opt_reg_string(odb, "-bpred",
"branch predictor type {nottaken|taken|perfect|bimod|2lev|comb}",
&pred_type, /* default */"bimod",
/* print */TRUE, /* format */NULL);
opt_reg_int_list(odb, "-bpred:bimod",
"bimodal predictor config (<table size>)",
bimod_config, bimod_nelt, &bimod_nelt,
/* default */bimod_config,
/* print */TRUE, /* format */NULL, /* !accrue */FALSE);
opt_reg_int_list(odb, "-bpred:2lev",
"2-level predictor config "
"(<l1size> <l2size> <hist_size> <xor>)",
twolev_config, twolev_nelt, &twolev_nelt,
/* default */twolev_config,
/* print */TRUE, /* format */NULL, /* !accrue */FALSE);
opt_reg_int_list(odb, "-bpred:comb",
"combining predictor config (<meta_table_size>)",
comb_config, comb_nelt, &comb_nelt,
/* default */comb_config,
/* print */TRUE, /* format */NULL, /* !accrue */FALSE);
opt_reg_int(odb, "-bpred:ras",
"return address stack size (0 for no return stack)",
&ras_size, /* default */ras_size,
/* print */TRUE, /* format */NULL);
opt_reg_int_list(odb, "-bpred:btb",
"BTB config (<num_sets> <associativity>)",
btb_config, btb_nelt, &btb_nelt,
/* default */btb_config,
/* print */TRUE, /* format */NULL, /* !accrue */FALSE);
opt_reg_string(odb, "-bpred:spec_update",
"speculative predictors update in {ID|WB} (default non-spec)",
&bpred_spec_opt, /* default */NULL,
/* print */TRUE, /* format */NULL);
/* decode options */
opt_reg_int(odb, "-decode:width",
"instruction decode B/W (insts/cycle)",
&ruu_decode_width, /* default */4,
/* print */TRUE, /* format */NULL);
/* issue options */
opt_reg_int(odb, "-issue:width",
"instruction issue B/W (insts/cycle)",
&ruu_issue_width, /* default */4,
/* print */TRUE, /* format */NULL);
opt_reg_flag(odb, "-issue:inorder", "run pipeline with in-order issue",
&ruu_inorder_issue, /* default */FALSE,
/* print */TRUE, /* format */NULL);
opt_reg_flag(odb, "-issue:wrongpath",
"issue instructions down wrong execution paths",
&ruu_include_spec, /* default */TRUE,
/* print */TRUE, /* format */NULL);
/* commit options */
opt_reg_int(odb, "-commit:width",
"instruction commit B/W (insts/cycle)",
&ruu_commit_width, /* default */4,
/* print */TRUE, /* format */NULL);
/* register scheduler options */
opt_reg_int(odb, "-ruu:size",
"register update unit (RUU) size",
&RUU_size, /* default */16,
/* print */TRUE, /* format */NULL);
/* memory scheduler options */
opt_reg_int(odb, "-lsq:size",
"load/store queue (LSQ) size",
&LSQ_size, /* default */8,
/* print */TRUE, /* format */NULL);
/* cache options */
opt_reg_string(odb, "-cache:dl1",
"l1 data cache config, i.e., {<config>|none}",
&cache_dl1_opt, "dl1:128:32:4:l",
/* print */TRUE, NULL);
opt_reg_note(odb,
" The cache config parameter <config> has the following format:\n"
"\n"
" <name>:<nsets>:<bsize>:<assoc>:<repl>\n"
"\n"
" <name> - name of the cache being defined\n"
" <nsets> - number of sets in the cache\n"
" <bsize> - block size of the cache\n"
" <assoc> - associativity of the cache\n"
" <repl> - block replacement strategy, 'l'-LRU, 'f'-FIFO, 'r'-random\n"
"\n"
" Examples: -cache:dl1 dl1:4096:32:1:l\n"
" -dtlb dtlb:128:4096:32:r\n"
);
opt_reg_int(odb, "-cache:dl1lat",
"l1 data cache hit latency (in cycles)",
&cache_dl1_lat, /* default */1,
/* print */TRUE, /* format */NULL);
opt_reg_string(odb, "-cache:dl2",
"l2 data cache config, i.e., {<config>|none}",
&cache_dl2_opt, "ul2:1024:64:4:l",
/* print */TRUE, NULL);
opt_reg_int(odb, "-cache:dl2lat",
"l2 data cache hit latency (in cycles)",
&cache_dl2_lat, /* default */6,
/* print */TRUE, /* format */NULL);
opt_reg_string(odb, "-cache:il1",
"l1 inst cache config, i.e., {<config>|dl1|dl2|none}",
&cache_il1_opt, "il1:512:32:1:l",
/* print */TRUE, NULL);
opt_reg_note(odb,
" Cache levels can be unified by pointing a level of the instruction cache\n"
" hierarchy at the data cache hiearchy using the \"dl1\" and \"dl2\" cache\n"
" configuration arguments. Most sensible combinations are supported, e.g.,\n"
"\n"
" A unified l2 cache (il2 is pointed at dl2):\n"
" -cache:il1 il1:128:64:1:l -cache:il2 dl2\n"
" -cache:dl1 dl1:256:32:1:l -cache:dl2 ul2:1024:64:2:l\n"
"\n"
" Or, a fully unified cache hierarchy (il1 pointed at dl1):\n"
" -cache:il1 dl1\n"
" -cache:dl1 ul1:256:32:1:l -cache:dl2 ul2:1024:64:2:l\n"
);
opt_reg_int(odb, "-cache:il1lat",
"l1 instruction cache hit latency (in cycles)",
&cache_il1_lat, /* default */1,
/* print */TRUE, /* format */NULL);
opt_reg_string(odb, "-cache:il2",
"l2 instruction cache config, i.e., {<config>|dl2|none}",
&cache_il2_opt, "dl2",
/* print */TRUE, NULL);
opt_reg_int(odb, "-cache:il2lat",
"l2 instruction cache hit latency (in cycles)",
&cache_il2_lat, /* default */6,
/* print */TRUE, /* format */NULL);
opt_reg_flag(odb, "-cache:flush", "flush caches on system calls",
&flush_on_syscalls, /* default */FALSE, /* print */TRUE, NULL);
opt_reg_flag(odb, "-cache:icompress",
"convert 64-bit inst addresses to 32-bit inst equivalents",
&compress_icache_addrs, /* default */FALSE,
/* print */TRUE, NULL);
/* mem options */
opt_reg_int_list(odb, "-mem:lat",
"memory access latency (<first_chunk> <inter_chunk>)",
mem_lat, mem_nelt, &mem_nelt, mem_lat,
/* print */TRUE, /* format */NULL, /* !accrue */FALSE);
opt_reg_int(odb, "-mem:width", "memory access bus width (in bytes)",
&mem_bus_width, /* default */8,
/* print */TRUE, /* format */NULL);
/* TLB options */
opt_reg_string(odb, "-tlb:itlb",
"instruction TLB config, i.e., {<config>|none}",
&itlb_opt, "itlb:16:4096:4:l", /* print */TRUE, NULL);
opt_reg_string(odb, "-tlb:dtlb",
"data TLB config, i.e., {<config>|none}",
&dtlb_opt, "dtlb:32:4096:4:l", /* print */TRUE, NULL);
opt_reg_int(odb, "-tlb:lat",
"inst/data TLB miss latency (in cycles)",
&tlb_miss_lat, /* default */30,
/* print */TRUE, /* format */NULL);
/* resource configuration */
opt_reg_int(odb, "-res:ialu",
"total number of integer ALU's available",
&res_ialu, /* default */fu_config[FU_IALU_INDEX].quantity,
/* print */TRUE, /* format */NULL);
opt_reg_int(odb, "-res:imult",
"total number of integer multiplier/dividers available",
&res_imult, /* default */fu_config[FU_IMULT_INDEX].quantity,
/* print */TRUE, /* format */NULL);
opt_reg_int(odb, "-res:memport",
"total number of memory system ports available (to CPU)",
&res_memport, /* default */fu_config[FU_MEMPORT_INDEX].quantity,
/* print */TRUE, /* format */NULL);
opt_reg_int(odb, "-res:fpalu",
"total number of floating point ALU's available",
&res_fpalu, /* default */fu_config[FU_FPALU_INDEX].quantity,
/* print */TRUE, /* format */NULL);
opt_reg_int(odb, "-res:fpmult",
"total number of floating point multiplier/dividers available",
&res_fpmult, /* default */fu_config[FU_FPMULT_INDEX].quantity,
/* print */TRUE, /* format */NULL);
opt_reg_string_list(odb, "-pcstat",
"profile stat(s) against text addr's (mult uses ok)",
pcstat_vars, MAX_PCSTAT_VARS, &pcstat_nelt, NULL,
/* !print */FALSE, /* format */NULL, /* accrue */TRUE);
opt_reg_flag(odb, "-bugcompat",
"operate in backward-compatible bugs mode (for testing only)",
&bugcompat_mode, /* default */FALSE, /* print */TRUE, NULL);
}
/* check simulator-specific option values */
void
sim_check_options(struct opt_odb_t *odb, /* options database */
int argc, char **argv) /* command line arguments */
{
char name[128], c;
int nsets, bsize, assoc;
if (fastfwd_count < 0 || fastfwd_count >= 2147483647)
fatal("bad fast forward count: %d", fastfwd_count);
if (ruu_ifq_size < 1 || (ruu_ifq_size & (ruu_ifq_size - 1)) != 0)
fatal("inst fetch queue size must be positive > 0 and a power of two");
if (ruu_branch_penalty < 1)
fatal("mis-prediction penalty must be at least 1 cycle");
if (fetch_speed < 1)
fatal("front-end speed must be positive and non-zero");
if (!mystricmp(pred_type, "perfect"))
{
/* perfect predictor */
pred = NULL;
pred_perfect = TRUE;
}
else if (!mystricmp(pred_type, "taken"))
{
/* static predictor, not taken */
pred = bpred_create(BPredTaken, 0, 0, 0, 0, 0, 0, 0, 0, 0);
}
else if (!mystricmp(pred_type, "nottaken"))
{
/* static predictor, taken */
pred = bpred_create(BPredNotTaken, 0, 0, 0, 0, 0, 0, 0, 0, 0);
}
else if (!mystricmp(pred_type, "bimod"))
{
/* bimodal predictor, bpred_create() checks BTB_SIZE */
if (bimod_nelt != 1)
fatal("bad bimod predictor config (<table_size>)");
if (btb_nelt != 2)
fatal("bad btb config (<num_sets> <associativity>)");
/* bimodal predictor, bpred_create() checks BTB_SIZE */
pred = bpred_create(BPred2bit,
/* bimod table size */bimod_config[0],
/* 2lev l1 size */0,
/* 2lev l2 size */0,
/* meta table size */0,
/* history reg size */0,
/* history xor address */0,
/* btb sets */btb_config[0],
/* btb assoc */btb_config[1],
/* ret-addr stack size */ras_size);
}
else if (!mystricmp(pred_type, "2lev"))
{
/* 2-level adaptive predictor, bpred_create() checks args */
if (twolev_nelt != 4)
fatal("bad 2-level pred config (<l1size> <l2size> <hist_size> <xor>)");
if (btb_nelt != 2)
fatal("bad btb config (<num_sets> <associativity>)");
pred = bpred_create(BPred2Level,
/* bimod table size */0,
/* 2lev l1 size */twolev_config[0],
/* 2lev l2 size */twolev_config[1],
/* meta table size */0,
/* history reg size */twolev_config[2],
/* history xor address */twolev_config[3],