Merge branch 'dev' into documentation

This commit is contained in:
AurelienUoU 2019-07-17 07:33:30 -06:00
commit 8b7f20f1ba
25 changed files with 372 additions and 186 deletions

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@ -12,3 +12,5 @@ RUN echo "cmake .. -DCMAKE_BUILD_TYPE=debug" >> build.sh
RUN echo "make" >> build.sh
RUN chmod +x build.sh
RUN ./build.sh
VOLUME /OpenFPGA

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@ -9,7 +9,11 @@ The OpenFPGA framework is the **first open-source FPGA IP generator** supporting
## Compilation
<<<<<<< HEAD
Dependancies and help using docker can be found at [**./tutorials/building.md**](https://github.com/LNIS-Projects/OpenFPGA/blob/master/tutorials/building.md).
=======
Dependencies and help using docker can be found at [**./tutorials/building.md**](https://github.com/LNIS-Projects/OpenFPGA/blob/master/tutorials/building.md).
>>>>>>> dev
**Compilation steps:**
1. git clone https://github.com/LNIS-Projects/OpenFPGA.git && cd OpenFPGA # *Clone the repository and go into it*
@ -20,7 +24,7 @@ Dependancies and help using docker can be found at [**./tutorials/building.md**]
*We currently implemented OpenFPGA for:*<br />
*1. Ubuntu 16.04*<br />
*2. Red Hat 7.5*<br />
*3. MacOS Mojiva 10.13.4*<br /><br />
*3. MacOS Mojave 10.13.4*<br /><br />
*Please note that those were the versions we tested the software for. It might work with earlier versions and other distributions.*
## Documentation

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@ -37,6 +37,7 @@ set_target_properties(libace PROPERTIES PREFIX "") #Avoid extra 'lib' prefix#Cre
# Specify dependency
target_link_libraries(libace
libabc
libvtrutil
${CMAKE_DL_LIBS})
add_executable(ace ${EXEC_SOURCES})

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@ -1,3 +1,6 @@
#include "vtr_assert.h"
#include "vtr_time.h" //For some reason this causes compilation errors if included below the std headers on with g++-5
#include "vtr_assert.h"
#include <stdio.h>
#include <inttypes.h>
@ -50,8 +53,7 @@ void print_status(Abc_Ntk_t * ntk) {
printf("%d: OLD\n", i);
break;
default:
printf("Invalid ABC object info status");
exit(1);
VTR_ASSERT_MSG(false, "Invalid ABC object info status");
}
}
}
@ -169,11 +171,11 @@ int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name) {
{
info = Ace_ObjInfo(obj);
if (strcmp(Abc_ObjName(obj), clk_name) != 0) {
assert(info->static_prob >= 0 && info->static_prob <= 1.0);
assert(info->switch_prob >= 0 && info->switch_prob <= 1.0);
assert(info->switch_act >= 0 && info->switch_act <= 1.0);
assert(info->switch_prob <= 2.0 * (1.0 - info->static_prob));
assert(info->switch_prob <= 2.0 * info->static_prob);
VTR_ASSERT(info->static_prob >= 0 && info->static_prob <= 1.0);
VTR_ASSERT(info->switch_prob >= 0 && info->switch_prob <= 1.0);
VTR_ASSERT(info->switch_act >= 0 && info->switch_act <= 1.0);
VTR_ASSERT(info->switch_prob <= 2.0 * (1.0 - info->static_prob));
VTR_ASSERT(info->switch_prob <= 2.0 * info->static_prob);
}
info->status = ACE_DEF;
}
@ -233,11 +235,11 @@ int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name) {
Ace_Obj_Info_t * info2 = Ace_ObjInfo(obj);
info2->switch_act = info2->switch_prob;
assert(info2->switch_act >= 0.0);
VTR_ASSERT(info2->switch_act >= 0.0);
}
Abc_NtkForEachPi(ntk, obj, i)
{
assert(Ace_ObjInfo(obj)->switch_act >= 0.0);
VTR_ASSERT(Ace_ObjInfo(obj)->switch_act >= 0.0);
}
/*------------- Calculate switching activities. ---------------------*/
@ -275,7 +277,7 @@ int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name) {
Ace_Obj_Info_t * info2 = Ace_ObjInfo(obj);
//Ace_Obj_Info_t * fanin_info2;
assert(Abc_ObjType(obj) == ABC_OBJ_NODE);
VTR_ASSERT(Abc_ObjType(obj) == ABC_OBJ_NODE);
if (Abc_ObjFaninNum(obj) < 1) {
info2->switch_act = 0.0;
@ -284,7 +286,7 @@ int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name) {
Vec_Ptr_t * literals = Vec_PtrAlloc(0);
Abc_Obj_t * fanin;
assert(obj->Type == ABC_OBJ_NODE);
VTR_ASSERT(obj->Type == ABC_OBJ_NODE);
Abc_ObjForEachFanin(obj, fanin, j)
{
@ -294,7 +296,7 @@ int ace_calc_activity(Abc_Ntk_t * ntk, int num_vectors, char * clk_name) {
literals);
Vec_PtrFree(literals);
}
assert(info2->switch_act >= 0);
VTR_ASSERT(info2->switch_act >= 0);
}
Vec_PtrFree(nodes_logic);
Vec_PtrFree(latches_in_cycles_vec);
@ -308,21 +310,22 @@ Ace_Obj_Info_t * Ace_ObjInfo(Abc_Obj_t * obj) {
if (st__lookup(ace_info_hash_table, (char *) obj, (char **) &info)) {
return info;
}
assert(0);
VTR_ASSERT(0);
return NULL;
}
void prob_epsilon_fix(double * d) {
if (*d < 0) {
assert(*d > 0 - EPSILON);
VTR_ASSERT(*d > 0 - EPSILON);
*d = 0;
} else if (*d > 1) {
assert(*d < 1 + EPSILON);
VTR_ASSERT(*d < 1 + EPSILON);
*d = 1.;
}
}
int main(int argc, char * argv[]) {
vtr::ScopedFinishTimer t("Ace");
FILE * BLIF = NULL;
FILE * IN_ACT = NULL;
FILE * OUT_ACT = stdout;
@ -351,7 +354,7 @@ int main(int argc, char * argv[]) {
ntk = Io_Read(blif_file_name, IO_FILE_BLIF, 1, 0);
assert(ntk);
VTR_ASSERT(ntk);
printf("Objects in network: %d\n", Abc_NtkObjNum(ntk));
printf("PIs in network: %d\n", Abc_NtkPiNum(ntk));
@ -383,7 +386,7 @@ int main(int argc, char * argv[]) {
// Check Depth
depth = ace_calc_network_depth(ntk);
printf("Max Depth: %d\n", depth);
assert(depth > 0);
VTR_ASSERT(depth > 0);
alloc_and_init_activity_info(ntk);

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@ -1,5 +1,7 @@
#include <inttypes.h>
#include "vtr_assert.h"
#include "ace.h"
#include "misc/vec/vecPtr.h"
#include "bdd.h"
@ -86,7 +88,7 @@ int ace_bdd_build_network_bdds(
int i;
Vec_Ptr_t * nodes;
assert(Vec_PtrSize(inputs) > 0);
VTR_ASSERT(Vec_PtrSize(inputs) > 0);
nodes = Abc_NtkDfsSeq(ntk);
@ -111,8 +113,8 @@ int ace_bdd_build_network_bdds(
switch (info->status)
{
case ACE_SIM:
assert (info->static_prob >= 0.0 && info->static_prob <= 1.0);
assert (info->switch_prob >= 0.0 && info->switch_prob <= 1.0);
VTR_ASSERT (info->static_prob >= 0.0 && info->static_prob <= 1.0);
VTR_ASSERT (info->switch_prob >= 0.0 && info->switch_prob <= 1.0);
if (!st_lookup(leaves, (char*) obj, NULL))
{
@ -128,7 +130,7 @@ int ace_bdd_build_network_bdds(
break;
case ACE_UNDEF:
assert(0);
VTR_ASSERT(0);
if (check_pi_status(obj))
{
while(1)
@ -149,14 +151,14 @@ int ace_bdd_build_network_bdds(
break;
case ACE_DEF:
assert(info->static_prob >= 0 && info->static_prob <= 1.0);
assert(info->switch_prob >= 0 && info->switch_prob <= 1.0);
VTR_ASSERT(info->static_prob >= 0 && info->static_prob <= 1.0);
VTR_ASSERT(info->switch_prob >= 0 && info->switch_prob <= 1.0);
break;
case ACE_NEW:
case ACE_OLD:
default:
assert(0);
VTR_ASSERT(0);
}
}
@ -192,7 +194,7 @@ double calc_cube_switch_prob_recur(DdManager * mgr, DdNode * bdd,
}
/* Get literal index for this bdd node. */
//assert(0);
//VTR_ASSERT(0);
i = Cudd_Regular(bdd)->index;
pi = (Abc_Obj_t*) Vec_PtrEntry((Vec_Ptr_t*) inputs, i);
@ -210,11 +212,11 @@ double calc_cube_switch_prob_recur(DdManager * mgr, DdNode * bdd,
then_prob = calc_cube_switch_prob_recur(mgr, bdd_if1, cube, inputs, visited,
phase);
assert(then_prob + EPSILON >= 0 && then_prob - EPSILON <= 1);
VTR_ASSERT(then_prob + EPSILON >= 0 && then_prob - EPSILON <= 1);
else_prob = calc_cube_switch_prob_recur(mgr, bdd_if0, cube, inputs, visited,
phase);
assert(else_prob + EPSILON >= 0 && else_prob - EPSILON <= 1);
VTR_ASSERT(else_prob + EPSILON >= 0 && else_prob - EPSILON <= 1);
switch (node_get_literal (cube->cube, i)) {
case ZERO:
@ -235,7 +237,7 @@ double calc_cube_switch_prob_recur(DdManager * mgr, DdNode * bdd,
st__insert(visited, (char *) bdd, (char *) current_prob);
assert(*current_prob + EPSILON >= 0 && *current_prob - EPSILON < 1.0);
VTR_ASSERT(*current_prob + EPSILON >= 0 && *current_prob - EPSILON < 1.0);
return (*current_prob);
}
@ -250,7 +252,7 @@ double calc_cube_switch_prob(DdManager * mgr, DdNode * bdd, ace_cube_t * cube,
st__free_table(visited);
assert(sp + EPSILON >= 0. && sp - EPSILON <= 1.0);
VTR_ASSERT(sp + EPSILON >= 0. && sp - EPSILON <= 1.0);
return (sp);
}
@ -264,9 +266,9 @@ double calc_switch_prob_recur(DdManager * mgr, DdNode * bdd_next, DdNode * bdd,
ace_cube_t * cube0, *cube1;
Ace_Obj_Info_t * info;
assert(inputs != NULL);
assert(Vec_PtrSize(inputs) > 0);
assert(P1 >= 0);
VTR_ASSERT(inputs != NULL);
VTR_ASSERT(Vec_PtrSize(inputs) > 0);
VTR_ASSERT(P1 >= 0);
if (bdd == Cudd_ReadLogicZero(mgr)) {
if (phase != 1)
@ -274,7 +276,7 @@ double calc_switch_prob_recur(DdManager * mgr, DdNode * bdd_next, DdNode * bdd,
prob = calc_cube_switch_prob(mgr, bdd_next, cube, inputs, phase);
prob *= P1;
assert(prob + EPSILON >= 0. && prob - EPSILON <= 1.);
VTR_ASSERT(prob + EPSILON >= 0. && prob - EPSILON <= 1.);
return (prob * P1);
} else if (bdd == Cudd_ReadOne(mgr)) {
if (phase != 0)
@ -282,7 +284,7 @@ double calc_switch_prob_recur(DdManager * mgr, DdNode * bdd_next, DdNode * bdd,
prob = calc_cube_switch_prob(mgr, bdd_next, cube, inputs, phase);
prob *= P1;
assert(prob + EPSILON >= 0. && prob - EPSILON <= 1.);
VTR_ASSERT(prob + EPSILON >= 0. && prob - EPSILON <= 1.);
return (prob * P1);
}
@ -315,8 +317,8 @@ double calc_switch_prob_recur(DdManager * mgr, DdNode * bdd_next, DdNode * bdd,
inputs, P1 * (1.0 - info->static_prob), phase);
ace_cube_free(cube0);
assert(switch_prob_t + EPSILON >= 0. && switch_prob_t - EPSILON <= 1.);
assert(switch_prob_e + EPSILON >= 0. && switch_prob_e - EPSILON <= 1.);
VTR_ASSERT(switch_prob_t + EPSILON >= 0. && switch_prob_t - EPSILON <= 1.);
VTR_ASSERT(switch_prob_e + EPSILON >= 0. && switch_prob_e - EPSILON <= 1.);
return (switch_prob_t + switch_prob_e);
}
@ -333,7 +335,7 @@ double ace_bdd_calc_switch_act(DdManager * mgr, Abc_Obj_t * obj,
DdNode * bdd;
d = info->depth;
assert(d > 0);
VTR_ASSERT(d > 0);
d = (int) d * 0.4;
if (d < 1) {
d = 1;
@ -361,10 +363,10 @@ double ace_bdd_calc_switch_act(DdManager * mgr, Abc_Obj_t * obj,
prob_epsilon_fix(&fanin_info->prob0to1);
prob_epsilon_fix(&fanin_info->prob1to0);
assert(
VTR_ASSERT(
fanin_info->prob0to1 + EPSILON >= 0.
&& fanin_info->prob0to1 - EPSILON <= 1.0);
assert(
VTR_ASSERT(
fanin_info->prob1to0 + EPSILON >= 0.
&& fanin_info->prob1to0 - EPSILON <= 1.0);
}

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@ -1,3 +1,4 @@
#include "vtr_assert.h"
#include "cube.h"
#include "bdd.h"
@ -16,8 +17,8 @@ ace_cube_t * ace_cube_dup(ace_cube_t * cube) {
int i;
ace_cube_t * cube_copy;
assert(cube != NULL);
assert(cube->num_literals > 0);
VTR_ASSERT(cube != NULL);
VTR_ASSERT(cube->num_literals > 0);
cube_copy = (ace_cube_t*) malloc(sizeof(ace_cube_t));
cube_copy->static_prob = cube->static_prob;
@ -63,8 +64,8 @@ ace_cube_t * ace_cube_new_dc(int num_literals) {
}
void ace_cube_free(ace_cube_t * cube) {
assert(cube != NULL);
assert(cube->cube != NULL);
VTR_ASSERT(cube != NULL);
VTR_ASSERT(cube->cube != NULL);
free(cube->cube);
free(cube);
}

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@ -1,3 +1,4 @@
#include "vtr_assert.h"
#include "cycle.h"
#include "ace.h"
@ -28,7 +29,7 @@ bool in_cycle(Abc_Ntk_t * ntk, int obj_id_to_find, Abc_Obj_t * starting_obj_ptr,
{
// Get BI of latch
fanin_ptr = Abc_ObjFanin0(Abc_ObjFanin0(starting_obj_ptr));
assert(fanin_ptr);
VTR_ASSERT(fanin_ptr);
return (in_cycle(ntk, obj_id_to_find, fanin_ptr, flag));
}

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@ -1,5 +1,7 @@
#include <stdlib.h>
#include "vtr_assert.h"
#include "ace.h"
#include "io_ace.h"
@ -34,7 +36,7 @@ void ace_io_print_activity(Abc_Ntk_t * ntk, FILE * fp) {
Abc_NtkForEachObj(ntk, obj, i)
{
assert(obj->pCopy);
VTR_ASSERT(obj->pCopy);
obj_new = obj->pCopy;
Ace_Obj_Info_t * info = Ace_ObjInfo(obj);
@ -69,7 +71,7 @@ void ace_io_print_activity(Abc_Ntk_t * ntk, FILE * fp) {
default:
//printf("Unkown Type: %d\n", Abc_ObjType(obj));
//assert(0);
//VTR_ASSERT(0);
break;
}
@ -235,10 +237,10 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
printf("Cannot open input file\n");
error = ACE_ERROR;
} else {
assert(p >= 0.0 && p <= 1.0);
assert(d >= 0.0 && d <= 1.0);
assert(d <= 2.0 * p);
assert(d <= 2.0 * (1.0 - p));
VTR_ASSERT(p >= 0.0 && p <= 1.0);
VTR_ASSERT(d >= 0.0 && d <= 1.0);
VTR_ASSERT(d <= 2.0 * p);
VTR_ASSERT(d <= 2.0 * (1.0 - p));
Abc_NtkForEachPi(ntk, obj_ptr, i)
{
@ -269,7 +271,7 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
// Read real PIs activity values from file
res = fgets(line, ACE_CHAR_BUFFER_SIZE, in_file_desc);
assert(res);
VTR_ASSERT(res);
while (!feof(in_file_desc)) {
sscanf(line, "%s %lf %lf\n", pi_name, &static_prob,
&switch_prob);
@ -283,8 +285,8 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
}
pi_obj_ptr = Abc_NtkObj(ntk, pi_obj_id);
assert(static_prob >= 0.0 && static_prob <= 1.0);
assert(switch_prob >= 0.0 && switch_prob <= 1.0);
VTR_ASSERT(static_prob >= 0.0 && static_prob <= 1.0);
VTR_ASSERT(switch_prob >= 0.0 && switch_prob <= 1.0);
info = Ace_ObjInfo(pi_obj_ptr);
info->static_prob = static_prob;
@ -292,7 +294,7 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
info->switch_act = switch_prob;
res = fgets(line, ACE_CHAR_BUFFER_SIZE, in_file_desc);
assert(res);
VTR_ASSERT(res);
}
} else if (pi_format == ACE_VEC) {
printf("Reading vector file...\n");
@ -305,10 +307,10 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
char* res;
res = fgets(line, ACE_CHAR_BUFFER_SIZE, in_file_desc);
assert(res);
VTR_ASSERT(res);
while (!feof(in_file_desc)) {
res = fgets(line, ACE_CHAR_BUFFER_SIZE, in_file_desc);
assert(res);
VTR_ASSERT(res);
num_vec++;
}
Abc_NtkForEachPi(ntk, obj_ptr, i)
@ -325,7 +327,7 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
num_vec = 0;
res = fgets(line, ACE_CHAR_BUFFER_SIZE, in_file_desc);
assert(res);
VTR_ASSERT(res);
while (!feof(in_file_desc)) {
sscanf(line, "%s\n", vector);
@ -336,7 +338,7 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
error = ACE_ERROR;
break;
}
assert(strlen(vector) == num_Pi);
VTR_ASSERT(strlen(vector) == num_Pi);
if (num_vec == 0) {
Abc_NtkForEachPi(ntk, obj_ptr, i)
@ -364,14 +366,14 @@ int ace_io_read_activity(Abc_Ntk_t * ntk, FILE * in_file_desc,
}
res = fgets(line, ACE_CHAR_BUFFER_SIZE, in_file_desc);
assert(res);
VTR_ASSERT(res);
num_vec++;
}
if (!error) {
Abc_NtkForEachPi(ntk, obj_ptr, i)
{
assert(num_vec > 0);
VTR_ASSERT(num_vec > 0);
info = Ace_ObjInfo(obj_ptr);
info->static_prob = (double) high[i] / (double) num_vec;

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@ -1,3 +1,4 @@
#include "vtr_assert.h"
#include "ace.h"
#include "sim.h"
@ -60,7 +61,7 @@ void get_pi_values(Abc_Ntk_t * ntk, Vec_Ptr_t * /*nodes*/, int cycle) {
default:
printf("Bad Value\n");
assert(0);
VTR_ASSERT(0);
break;
}
}
@ -111,7 +112,7 @@ void get_pi_values(Abc_Ntk_t * ntk, Vec_Ptr_t * /*nodes*/, int cycle) {
default:
printf("Bad value\n");
assert(FALSE);
VTR_ASSERT(FALSE);
break;
}
}
@ -131,7 +132,7 @@ int * getFaninValues(Abc_Obj_t * obj_ptr) {
info = Ace_ObjInfo(fanin);
if (info->status == ACE_UNDEF) {
printf("Fan-in is undefined\n");
assert(FALSE);
VTR_ASSERT(FALSE);
} else if (info->status == ACE_NEW) {
break;
}
@ -210,15 +211,15 @@ void evaluate_circuit(Abc_Ntk_t * ntk, Vec_Ptr_t * node_vec, int /*cycle*/) {
case ACE_NEW:
if (Abc_ObjIsNode(obj)) {
faninValues = getFaninValues(obj);
assert(faninValues);
VTR_ASSERT(faninValues);
dd_node = Cudd_Eval((DdManager*) ntk->pManFunc, (DdNode*) obj->pData, faninValues);
assert(Cudd_IsConstant(dd_node));
VTR_ASSERT(Cudd_IsConstant(dd_node));
if (dd_node == Cudd_ReadOne((DdManager*) ntk->pManFunc)) {
value = 1;
} else if (dd_node == Cudd_ReadLogicZero((DdManager*) ntk->pManFunc)) {
value = 0;
} else {
assert(0);
VTR_ASSERT(0);
}
free(faninValues);
} else {
@ -240,12 +241,12 @@ void evaluate_circuit(Abc_Ntk_t * ntk, Vec_Ptr_t * node_vec, int /*cycle*/) {
info->num_ones += info->value;
break;
default:
assert(0);
VTR_ASSERT(0);
break;
}
break;
default:
assert(0);
VTR_ASSERT(0);
break;
}
}
@ -294,8 +295,8 @@ void ace_sim_activities(Abc_Ntk_t * ntk, Vec_Ptr_t * nodes, int max_cycles,
Ace_Obj_Info_t * info;
int i;
assert(max_cycles > 0);
assert(threshold > 0.0);
VTR_ASSERT(max_cycles > 0);
VTR_ASSERT(threshold > 0.0);
// srand((unsigned) time(NULL));
@ -326,12 +327,12 @@ void ace_sim_activities(Abc_Ntk_t * ntk, Vec_Ptr_t * nodes, int max_cycles,
{
info = Ace_ObjInfo(obj);
info->static_prob = info->num_ones / (double) max_cycles;
assert(info->static_prob >= 0.0 && info->static_prob <= 1.0);
VTR_ASSERT(info->static_prob >= 0.0 && info->static_prob <= 1.0);
info->switch_prob = info->num_toggles / (double) max_cycles;
assert(info->switch_prob >= 0.0 && info->switch_prob <= 1.0);
VTR_ASSERT(info->switch_prob >= 0.0 && info->switch_prob <= 1.0);
assert(info->switch_prob - EPSILON <= 2.0 * (1.0 - info->static_prob));
assert(info->switch_prob - EPSILON <= 2.0 * (info->static_prob));
VTR_ASSERT(info->switch_prob - EPSILON <= 2.0 * (1.0 - info->static_prob));
VTR_ASSERT(info->switch_prob - EPSILON <= 2.0 * (info->static_prob));
info->status = ACE_SIM;
}

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@ -397,7 +397,7 @@
<port type="output" prefix="inpad" size="1"/>
</circuit_model>
<!-- Hard logic definition for heterogenous blocks -->
<circuit_model type="hard_logic" name="adder" prefix="adder" dump_explicit_port_map="true" spice_netlist="OPENFPGAPATHKEYWORD/vpr7_x2p/vpr/SpiceNetlists/adder.sp" verilog_netlist="OPENFPGAPATHKEYWORD/vpr7_x2p/vpr/VerilogNetlists/adder.v">
<circuit_model type="hard_logic" name="adder" prefix="adder" dump_explicit_port_map="false" spice_netlist="OPENFPGAPATHKEYWORD/vpr7_x2p/vpr/SpiceNetlists/adder.sp" verilog_netlist="OPENFPGAPATHKEYWORD/vpr7_x2p/vpr/VerilogNetlists/adder.v">
<design_technology type="cmos"/>
<input_buffer exist="on" circuit_model_name="INV1X"/>
<output_buffer exist="on" circuit_model_name="INV1X"/>

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@ -273,7 +273,7 @@
<port type="input" prefix="Set" size="1" is_global="true" default_val="0" is_set="true"/>
<port type="input" prefix="Reset" size="1" is_global="true" default_val="1" is_reset="true"/>
<port type="output" prefix="Q" size="1"/>
<port type="clock" prefix="clk" size="1" is_global="true" default_val="0" />
<port type="clock" prefix="CK" size="1" is_global="true" default_val="0" />
</circuit_model>
<circuit_model type="lut" name="frac_lut6" prefix="frac_lut6" dump_structural_verilog="true">
<design_technology type="cmos" fracturable_lut="true"/>
@ -300,7 +300,7 @@
<port type="input" prefix="D" size="1"/>
<port type="output" prefix="Q" size="1"/>
<port type="output" prefix="Qb" size="1"/>
<port type="clock" prefix="prog_clk" size="1" is_global="true" default_val="0" is_prog="true"/>
<port type="clock" prefix="prog_CK" size="1" is_global="true" default_val="0" is_prog="true"/>
</circuit_model>
<circuit_model type="iopad" name="iopad" prefix="iopad" spice_netlist="/research/ece/lnis/USERS/alacchi/Current_release/OpenFPGA/vpr7_x2p/vpr/SpiceNetlists/io.sp" verilog_netlist="/research/ece/lnis/USERS/alacchi/Current_release/OpenFPGA/vpr7_x2p/vpr/VerilogNetlists/io.v">
<design_technology type="cmos"/>
@ -515,7 +515,7 @@
<input name="cin" num_pins="1"/>
<output name="O" num_pins="20" equivalent="false"/>
<output name="cout" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<!-- Describe fracturable logic element.
Each fracturable logic element has a 6-LUT that can alternatively operate as two 5-LUTs with shared inputs.
@ -526,7 +526,7 @@
<input name="cin" num_pins="1"/>
<output name="out" num_pins="2"/>
<output name="cout" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<mode name="fle_phy" disabled_in_packing="true">
<pb_type name="frac_logic" num_pb="1">
@ -571,12 +571,12 @@
<pb_type name="ff_phy" blif_model=".latch" num_pb="2" class="flipflop" circuit_model_name="static_dff">
<input name="D" num_pins="1" port_class="D"/>
<output name="Q" num_pins="1" port_class="Q"/>
<clock name="clk" num_pins="1" port_class="clock"/>
<T_setup value="66e-12" port="ff_phy.D" clock="clk"/>
<T_clock_to_Q max="124e-12" port="ff_phy.Q" clock="clk"/>
<clock name="CK" num_pins="1" port_class="clock"/>
<T_setup value="66e-12" port="ff_phy.D" clock="CK"/>
<T_clock_to_Q max="124e-12" port="ff_phy.Q" clock="CK"/>
</pb_type>
<interconnect>
<complete name="direct_clk" input="fle.clk" output="ff_phy[1:0].clk"/>
<complete name="direct_CK" input="fle.CK" output="ff_phy[1:0].CK"/>
<direct name="direct_in" input="fle.in[5:0]" output="frac_logic.in[5:0]"/>
<direct name="direct_cin" input="fle.cin" output="frac_logic.cin"/>
<direct name="direct_cout" input="frac_logic.cout" output="fle.cout"/>
@ -595,18 +595,18 @@
<input name="cin" num_pins="1"/>
<output name="out" num_pins="2"/>
<output name="cout" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<pb_type name="ble5" num_pb="2" idle_mode_name="blut5">
<input name="in" num_pins="5"/>
<input name="cin" num_pins="1"/>
<output name="out" num_pins="1"/>
<output name="cout" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<mode name="blut5">
<pb_type name="flut5" num_pb="1">
<input name="in" num_pins="5"/>
<output name="out" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<!-- Regular LUT mode -->
<pb_type name="lut5" blif_model=".names" num_pb="1" class="lut" mode_bits="01" physical_pb_type_name="frac_lut6" physical_pb_type_index_factor="0.5">
<input name="in" num_pins="5" port_class="lut_in" physical_mode_pin="in[5:0]"/>
@ -632,16 +632,16 @@
<pb_type name="ff" blif_model=".latch" num_pb="1" class="flipflop" physical_pb_type_name="ff_phy">
<input name="D" num_pins="1" port_class="D" physical_mode_pin="D"/>
<output name="Q" num_pins="1" port_class="Q" physical_mode_pin="Q"/>
<clock name="clk" num_pins="1" port_class="clock" physical_mode_pin="clk"/>
<T_setup value="66e-12" port="ff.D" clock="clk"/>
<T_clock_to_Q max="124e-12" port="ff.Q" clock="clk"/>
<clock name="CK" num_pins="1" port_class="clock" physical_mode_pin="CK"/>
<T_setup value="66e-12" port="ff.D" clock="CK"/>
<T_clock_to_Q max="124e-12" port="ff.Q" clock="CK"/>
</pb_type>
<interconnect>
<direct name="direct1" input="flut5.in" output="lut5.in"/>
<direct name="direct2" input="lut5.out" output="ff.D">
<pack_pattern name="ble5" in_port="lut5.out" out_port="ff.D"/>
</direct>
<direct name="direct3" input="flut5.clk" output="ff.clk"/>
<direct name="direct3" input="flut5.CK" output="ff.CK"/>
<mux name="mux1" input="ff.Q lut5.out" output="flut5.out" spice_model_sram_offset="0">
<delay_constant max="25e-12" in_port="lut5.out" out_port="flut5.out" />
<delay_constant max="45e-12" in_port="ff.Q" out_port="flut5.out" />
@ -650,7 +650,7 @@
</pb_type>
<interconnect>
<direct name="direct1" input="ble5.in" output="flut5.in"/>
<direct name="direct2" input="ble5.clk" output="flut5.clk"/>
<direct name="direct2" input="ble5.CK" output="flut5.CK"/>
<direct name="direct3" input="flut5.out" output="ble5.out"/>
</interconnect>
</mode>
@ -660,7 +660,7 @@
<input name="cin" num_pins="1"/>
<output name="out" num_pins="1"/>
<output name="cout" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<!-- Special dual-LUT mode that drives adder only -->
<pb_type name="lut4" blif_model=".names" num_pb="2" class="lut" mode_bits="11" physical_pb_type_name="frac_lut6" physical_pb_type_index_factor="0.25">
<input name="in" num_pins="4" port_class="lut_in" physical_mode_pin="in[4:0]"/>
@ -696,12 +696,12 @@
<pb_type name="ff" blif_model=".latch" num_pb="1" class="flipflop" physical_pb_type_name="ff_phy">
<input name="D" num_pins="1" port_class="D" physical_mode_pin="D"/>
<output name="Q" num_pins="1" port_class="Q" physical_mode_pin="Q"/>
<clock name="clk" num_pins="1" port_class="clock" physical_mode_pin="clk"/>
<T_setup value="66e-12" port="ff.D" clock="clk"/>
<T_clock_to_Q max="124e-12" port="ff.Q" clock="clk"/>
<clock name="CK" num_pins="1" port_class="clock" physical_mode_pin="CK"/>
<T_setup value="66e-12" port="ff.D" clock="CK"/>
<T_clock_to_Q max="124e-12" port="ff.Q" clock="CK"/>
</pb_type>
<interconnect>
<direct name="clock" input="arithmetic.clk" output="ff.clk"/>
<direct name="clock" input="arithmetic.CK" output="ff.CK"/>
<direct name="lut_in1" input="arithmetic.in[3:0]" output="lut4[0:0].in[3:0]"/>
<direct name="lut_in2" input="arithmetic.in[3:0]" output="lut4[1:1].in[3:0]"/>
<direct name="lut_to_add1" input="lut4[0:0].out" output="adder.a">
@ -732,7 +732,7 @@
<direct name="carry_out" input="arithmetic.cout" output="ble5.cout">
<pack_pattern name="chain" in_port="arithmetic.cout" out_port="ble5.cout"/>
</direct>
<direct name="direct2" input="ble5.clk" output="arithmetic.clk"/>
<direct name="direct2" input="ble5.CK" output="arithmetic.CK"/>
<direct name="direct3" input="arithmetic.out" output="ble5.out"/>
</interconnect>
</mode>
@ -750,13 +750,13 @@
<direct name="carry_link" input="ble5[0:0].cout" output="ble5[1:1].cin">
<pack_pattern name="chain" in_port="ble5[0:0].cout" out_port="ble5[1:1].cout"/>
</direct>
<complete name="complete1" input="lut5inter.clk" output="ble5[1:0].clk"/>
<complete name="complete1" input="lut5inter.CK" output="ble5[1:0].CK"/>
</interconnect>
</pb_type>
<interconnect>
<direct name="direct1" input="fle.in[4:0]" output="lut5inter.in"/>
<direct name="direct2" input="lut5inter.out" output="fle.out"/>
<direct name="direct3" input="fle.clk" output="lut5inter.clk"/>
<direct name="direct3" input="fle.CK" output="lut5inter.CK"/>
<direct name="carry_in" input="fle.cin" output="lut5inter.cin">
<pack_pattern name="chain" in_port="fle.cin" out_port="lut5inter.cin"/>
</direct>
@ -769,7 +769,7 @@
<pb_type name="ble6" num_pb="1">
<input name="in" num_pins="6"/>
<output name="out" num_pins="1"/>
<clock name="clk" num_pins="1"/>
<clock name="CK" num_pins="1"/>
<pb_type name="lut6" blif_model=".names" num_pb="1" class="lut" mode_bits="00" physical_pb_type_name="frac_lut6" spice_model_sram_offset="0">
<input name="in" num_pins="6" port_class="lut_in" physical_mode_pin="in[5:0]"/>
<output name="out" num_pins="1" port_class="lut_out" physical_mode_pin="lut6_out[0]"/>
@ -795,9 +795,9 @@
<pb_type name="ff" blif_model=".latch" num_pb="1" class="flipflop" physical_pb_type_name="ff_phy" physical_pb_type_index_factor="2" physical_pb_type_index_offset="1">
<input name="D" num_pins="1" port_class="D" physical_mode_pin="D"/>
<output name="Q" num_pins="1" port_class="Q" physical_mode_pin="Q"/>
<clock name="clk" num_pins="1" port_class="clock" physical_mode_pin="clk"/>
<T_setup value="66e-12" port="ff.D" clock="clk"/>
<T_clock_to_Q max="124e-12" port="ff.Q" clock="clk"/>
<clock name="CK" num_pins="1" port_class="clock" physical_mode_pin="CK"/>
<T_setup value="66e-12" port="ff.D" clock="CK"/>
<T_clock_to_Q max="124e-12" port="ff.Q" clock="CK"/>
</pb_type>
<interconnect>
@ -805,7 +805,7 @@
<direct name="direct2" input="lut6.out" output="ff.D">
<pack_pattern name="ble6" in_port="lut6.out" out_port="ff.D"/>
</direct>
<direct name="direct3" input="ble6.clk" output="ff.clk"/>
<direct name="direct3" input="ble6.CK" output="ff.CK"/>
<mux name="mux1" input="ff.Q lut6.out" output="ble6.out">
<delay_constant max="25e-12" in_port="lut6.out" out_port="ble6.out" />
<delay_constant max="45e-12" in_port="ff.Q" out_port="ble6.out" />
@ -815,7 +815,7 @@
<interconnect>
<direct name="direct1" input="fle.in" output="ble6.in"/>
<direct name="direct2" input="ble6.out" output="fle.out[1:1]"/>
<direct name="direct3" input="fle.clk" output="ble6.clk"/>
<direct name="direct3" input="fle.CK" output="ble6.CK"/>
</interconnect>
</mode> <!-- n1_lut6 -->
</pb_type>
@ -833,7 +833,7 @@
<delay_constant max="95e-12" in_port="clb.I" out_port="fle[9:0].in" />
<delay_constant max="75e-12" in_port="fle[9:0].out" out_port="fle[9:0].in" />
</complete>
<complete name="clks" input="clb.clk" output="fle[9:0].clk">
<complete name="CKs" input="clb.CK" output="fle[9:0].CK">
</complete>
<!-- This way of specifying direct connection to clb outputs is important because this architecture uses automatic spreading of opins.

View File

@ -1143,17 +1143,26 @@ void sort_rr_gsb_one_ipin_node_drive_rr_nodes(const RRGSB& rr_gsb,
/* Create a copy of the edges and switches of this node */
std::vector<t_rr_node*> sorted_drive_nodes;
std::vector<int> sorted_drive_switches;
std::vector<int> sorted_drive_nodes_chan_node_index;
/* Ensure a clean start */
sorted_drive_nodes.clear();
sorted_drive_switches.clear();
/* Ensure a clean start and avoid frequent realloc */
sorted_drive_nodes.reserve(ipin_node->num_drive_rr_nodes);
sorted_drive_switches.reserve(ipin_node->num_drive_rr_nodes);
sorted_drive_nodes_chan_node_index.reserve(ipin_node->num_drive_rr_nodes);
/* Build the vectors w.r.t. to the order of node_type and ptc_num */
for (int i_from_node = 0; i_from_node < ipin_node->num_drive_rr_nodes; ++i_from_node) {
int i_from_node_track_index = rr_gsb.get_chan_node_index(ipin_chan_side, ipin_node->drive_rr_nodes[i_from_node]);
/* We must have a valide node index for CHANX and CHANY */
if ( (CHANX == ipin_node->drive_rr_nodes[i_from_node]->type)
|| (CHANY == ipin_node->drive_rr_nodes[i_from_node]->type) ) {
assert (-1 != i_from_node_track_index);
}
/* For blank edges: directly push_back */
if (0 == sorted_drive_nodes.size()) {
sorted_drive_nodes.push_back(ipin_node->drive_rr_nodes[i_from_node]);
sorted_drive_switches.push_back(ipin_node->drive_switches[i_from_node]);
sorted_drive_nodes_chan_node_index.push_back(i_from_node_track_index);
continue;
}
@ -1167,12 +1176,8 @@ void sort_rr_gsb_one_ipin_node_drive_rr_nodes(const RRGSB& rr_gsb,
break; /* least type should stay in the front of the vector */
} else if (ipin_node->drive_rr_nodes[i_from_node]->type
== sorted_drive_nodes[j_from_node]->type) {
int i_from_node_track_index = rr_gsb.get_chan_node_index(ipin_chan_side, ipin_node->drive_rr_nodes[i_from_node]);
int j_from_node_track_index = rr_gsb.get_chan_node_index(ipin_chan_side, sorted_drive_nodes[j_from_node]);
/* We must have a valide node index */
assert ( (-1 != i_from_node_track_index) && (-1 != j_from_node_track_index) );
/* Now a lower ptc_num will win */
if ( i_from_node_track_index < j_from_node_track_index ) {
if ( i_from_node_track_index < sorted_drive_nodes_chan_node_index[j_from_node] ) {
insert_pos = j_from_node;
break; /* least type should stay in the front of the vector */
}
@ -1181,6 +1186,7 @@ void sort_rr_gsb_one_ipin_node_drive_rr_nodes(const RRGSB& rr_gsb,
/* We find the position, inserted to the vector */
sorted_drive_nodes.insert(sorted_drive_nodes.begin() + insert_pos, ipin_node->drive_rr_nodes[i_from_node]);
sorted_drive_switches.insert(sorted_drive_switches.begin() + insert_pos, ipin_node->drive_switches[i_from_node]);
sorted_drive_nodes_chan_node_index.insert(sorted_drive_nodes_chan_node_index.begin() + insert_pos, i_from_node_track_index);
}
/* Overwrite the edges and switches with sorted numbers */
@ -1213,17 +1219,26 @@ void sort_rr_gsb_one_chan_node_drive_rr_nodes(const RRGSB& rr_gsb,
/* Create a copy of the edges and switches of this node */
std::vector<t_rr_node*> sorted_drive_nodes;
std::vector<int> sorted_drive_switches;
std::vector<int> sorted_drive_nodes_from_node_index;
/* Ensure a clean start */
sorted_drive_nodes.clear();
sorted_drive_switches.clear();
/* Ensure a clean start and avoid frequent realloc */
sorted_drive_nodes.reserve(chan_node->num_drive_rr_nodes);
sorted_drive_switches.reserve(chan_node->num_drive_rr_nodes);
sorted_drive_nodes_from_node_index.reserve(chan_node->num_drive_rr_nodes);
/* Build the vectors w.r.t. to the order of node_type and ptc_num */
for (int i_from_node = 0; i_from_node < chan_node->num_drive_rr_nodes; ++i_from_node) {
enum e_side i_from_node_side = NUM_SIDES;
int i_from_node_index = -1;
rr_gsb.get_node_side_and_index(chan_node->drive_rr_nodes[i_from_node],
IN_PORT, &i_from_node_side, &i_from_node_index);
/* check */
assert ( (NUM_SIDES != i_from_node_side) && (-1 != i_from_node_index) );
/* For blank edges: directly push_back */
if (0 == sorted_drive_nodes.size()) {
sorted_drive_nodes.push_back(chan_node->drive_rr_nodes[i_from_node]);
sorted_drive_switches.push_back(chan_node->drive_switches[i_from_node]);
sorted_drive_nodes_from_node_index.push_back(i_from_node_index);
continue;
}
@ -1241,22 +1256,9 @@ void sort_rr_gsb_one_chan_node_drive_rr_nodes(const RRGSB& rr_gsb,
* But we are pretty sure it is either IN_PORT or OUT_PORT
* So we just try and find what is valid
*/
enum e_side i_from_node_side = NUM_SIDES;
int i_from_node_index = -1;
rr_gsb.get_node_side_and_index(chan_node->drive_rr_nodes[i_from_node],
IN_PORT, &i_from_node_side, &i_from_node_index);
/* check */
if (! ( (NUM_SIDES != i_from_node_side) && (-1 != i_from_node_index) ) )
assert ( (NUM_SIDES != i_from_node_side) && (-1 != i_from_node_index) );
enum e_side j_from_node_side = NUM_SIDES;
int j_from_node_index = -1;
rr_gsb.get_node_side_and_index(sorted_drive_nodes[j_from_node],
IN_PORT, &j_from_node_side, &j_from_node_index);
/* check */
assert ( (NUM_SIDES != j_from_node_side) && (-1 != j_from_node_index) );
/* Now a lower ptc_num will win */
if ( i_from_node_index < j_from_node_index) {
if ( i_from_node_index < sorted_drive_nodes_from_node_index[j_from_node]) {
insert_pos = j_from_node;
break; /* least type should stay in the front of the vector */
}
@ -1265,6 +1267,7 @@ void sort_rr_gsb_one_chan_node_drive_rr_nodes(const RRGSB& rr_gsb,
/* We find the position, inserted to the vector */
sorted_drive_nodes.insert(sorted_drive_nodes.begin() + insert_pos, chan_node->drive_rr_nodes[i_from_node]);
sorted_drive_switches.insert(sorted_drive_switches.begin() + insert_pos, chan_node->drive_switches[i_from_node]);
sorted_drive_nodes_from_node_index.insert(sorted_drive_nodes_from_node_index.begin() + insert_pos, i_from_node_index);
}
/* Overwrite the edges and switches with sorted numbers */
@ -1339,9 +1342,11 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
DeviceCoordinator reserve_range((size_t)nx + 1, (size_t)ny + 1);
LL_device_rr_gsb.reserve(reserve_range);
size_t gsb_cnt = 0;
/* For each switch block, determine the size of array */
for (size_t ix = 0; ix <= sb_range.get_x(); ++ix) {
for (size_t iy = 0; iy <= sb_range.get_y(); ++iy) {
gsb_cnt++; /* Update counter */
const RRGSB& rr_gsb = build_rr_gsb(sb_range, ix, iy,
LL_num_rr_nodes, LL_rr_node,
LL_rr_node_indices,
@ -1358,6 +1363,11 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
/* Add to device_rr_gsb */
DeviceCoordinator sb_coordinator = rr_gsb.get_sb_coordinator();
LL_device_rr_gsb.add_rr_gsb(sb_coordinator, rr_gsb);
/* Print info */
vpr_printf(TIO_MESSAGE_INFO,
"[%lu%] Backannotated GSB[%lu][%lu]\r",
100 * gsb_cnt / ((sb_range.get_x() + 1)* (sb_range.get_y() + 1)),
ix, iy );
}
}
/* Report number of unique mirrors */
@ -1369,9 +1379,9 @@ DeviceRRGSB build_device_rr_gsb(boolean output_sb_xml, char* sb_xml_dir,
t_end = clock();
run_time_sec = (float)(t_end - t_start) / CLOCKS_PER_SEC;
vpr_printf(TIO_MESSAGE_INFO, "Edge sorting for Switch Block took %g seconds\n", run_time_sec_profiling);
vpr_printf(TIO_MESSAGE_INFO, "Backannotation of Switch Block took %g seconds\n\n", run_time_sec);
vpr_printf(TIO_MESSAGE_INFO, "Edge sorting for Switch Block took %g seconds\n\n", run_time_sec_profiling);
if (TRUE == output_sb_xml) {

View File

@ -2432,7 +2432,7 @@ const RRGSB DeviceRRGSB::get_sb_unique_module(size_t index) const {
}
/* Get a rr switch block which a unique mirror */
const RRGSB DeviceRRGSB::get_cb_unique_module(t_rr_type cb_type, size_t index) const {
const RRGSB& DeviceRRGSB::get_cb_unique_module(t_rr_type cb_type, size_t index) const {
assert (validate_cb_unique_module_index(cb_type, index));
assert (validate_cb_type(cb_type));
switch(cb_type) {
@ -2449,7 +2449,7 @@ const RRGSB DeviceRRGSB::get_cb_unique_module(t_rr_type cb_type, size_t index) c
}
/* Give a coordinator of a rr switch block, and return its unique mirror */
const RRGSB DeviceRRGSB::get_cb_unique_module(t_rr_type cb_type, DeviceCoordinator& coordinator) const {
const RRGSB& DeviceRRGSB::get_cb_unique_module(t_rr_type cb_type, DeviceCoordinator& coordinator) const {
assert (validate_cb_type(cb_type));
assert(validate_coordinator(coordinator));
size_t cb_unique_module_id;
@ -2659,7 +2659,8 @@ void DeviceRRGSB::build_cb_unique_module(t_rr_type cb_type) {
/* Traverse the unique_mirror list and check it is an mirror of another */
for (size_t id = 0; id < get_num_cb_unique_module(cb_type); ++id) {
if (true == rr_gsb_[ix][iy].is_cb_mirror(get_cb_unique_module(cb_type, id), cb_type)) {
const RRGSB& unique_module = get_cb_unique_module(cb_type, id);
if (true == rr_gsb_[ix][iy].is_cb_mirror(unique_module, cb_type)) {
/* This is a mirror, raise the flag and we finish */
is_unique_module = false;
/* Record the id of unique mirror */
@ -3109,7 +3110,7 @@ bool DeviceRRGSB::validate_cb_unique_module_index(t_rr_type cb_type, size_t inde
}
return true;
case CHANY:
if (index >= cbx_unique_module_.size()) {
if (index >= cby_unique_module_.size()) {
return false;
}
return true;

View File

@ -339,8 +339,8 @@ class DeviceRRGSB {
const RRGSB get_sb_unique_submodule(DeviceCoordinator& coordinator, enum e_side side, size_t seg_id) const; /* Get a rr switch block which a unique mirror */
const RRGSB get_sb_unique_module(size_t index) const; /* Get a rr switch block which a unique mirror */
const RRGSB get_sb_unique_module(DeviceCoordinator& coordinator) const; /* Get a rr switch block which a unique mirror */
const RRGSB get_cb_unique_module(t_rr_type cb_type, size_t index) const; /* Get a rr switch block which a unique mirror */
const RRGSB get_cb_unique_module(t_rr_type cb_type, DeviceCoordinator& coordinator) const;
const RRGSB& get_cb_unique_module(t_rr_type cb_type, size_t index) const; /* Get a rr switch block which a unique mirror */
const RRGSB& get_cb_unique_module(t_rr_type cb_type, DeviceCoordinator& coordinator) const;
size_t get_max_num_sides() const; /* Get the maximum number of sides across the switch blocks */
size_t get_num_segments() const; /* Get the size of segment_ids */
size_t get_segment_id(size_t index) const; /* Get a segment id */

View File

@ -1340,7 +1340,8 @@ void dump_compact_verilog_top_netlist(t_sram_orgz_info* cur_sram_orgz_info,
dump_verilog_clb2clb_directs(fp, num_clb2clb_directs, clb2clb_direct);
/* Dump configuration circuits */
dump_verilog_configuration_circuits(cur_sram_orgz_info, fp);
dump_verilog_configuration_circuits(cur_sram_orgz_info, fp,
is_explicit_mapping);
/* verilog ends*/
fprintf(fp, "endmodule\n");

View File

@ -370,7 +370,7 @@ void dump_verilog_pb_type_one_bus_port(FILE* fp,
port_prefix, pb_type_port->name);
} else {
if (TRUE == dump_explicit_port_map) {
fprintf(fp, ".%s(",
fprintf(fp, ".%s (",
pb_type_port->spice_model_port->lib_name);
}
if (1 < pb_type_port->num_pins) {
@ -1072,6 +1072,10 @@ void dump_verilog_pb_graph_pin_interc(t_sram_orgz_info* cur_sram_orgz_info,
char* mem_subckt_name = NULL;
char* hierarchical_name = NULL;
char* mux_name = NULL;
int num_input_port;
int num_output_port;
t_spice_model_port** input_port;
t_spice_model_port** output_port;
/* Check the file handler*/
if (NULL == fp) {
@ -1087,6 +1091,8 @@ void dump_verilog_pb_graph_pin_interc(t_sram_orgz_info* cur_sram_orgz_info,
fan_in = 0;
cur_interc = NULL;
find_interc_fan_in_des_pb_graph_pin(des_pb_graph_pin, cur_mode, &cur_interc, &fan_in);
input_port = find_spice_model_ports(cur_interc->spice_model, SPICE_MODEL_PORT_INPUT, &num_input_port, TRUE);
output_port = find_spice_model_ports(cur_interc->spice_model, SPICE_MODEL_PORT_OUTPUT, &num_output_port, TRUE);
if ((NULL == cur_interc)||(0 == fan_in)) {
/* No interconnection matched */
/* Connect this pin to GND for better convergence */
@ -1136,7 +1142,7 @@ void dump_verilog_pb_graph_pin_interc(t_sram_orgz_info* cur_sram_orgz_info,
fprintf(fp, "%s_%d_ (", cur_interc->spice_model->prefix, cur_interc->spice_model->cnt);
cur_interc->spice_model->cnt++; /* Stats the number of spice_model used*/
/* Dump global ports */
if (0 < rec_dump_verilog_spice_model_global_ports(fp, cur_interc->spice_model, FALSE, FALSE, FALSE)) {
if (0 < rec_dump_verilog_spice_model_global_ports(fp, cur_interc->spice_model, FALSE, FALSE, my_bool_to_boolean(is_explicit_mapping))) {
fprintf(fp, ",\n");
}
/* Print the pin names! Input and output
@ -1147,11 +1153,26 @@ void dump_verilog_pb_graph_pin_interc(t_sram_orgz_info* cur_sram_orgz_info,
/* Make sure correctness*/
assert(src_pb_type == des_pb_graph_pin->input_edges[iedge]->input_pins[0]->port->parent_pb_type);
/* Print */
fprintf(fp, "%s__%s_%d_, ",
if (true == is_explicit_mapping) {
fprintf(fp, ".%s(",
input_port[0]->prefix);
}
fprintf(fp, "%s__%s_%d_",
src_pin_prefix, src_pb_graph_pin->port->name, src_pb_graph_pin->pin_number);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
fprintf(fp, ", ");
/* Output */
fprintf(fp, "%s__%s_%d_ ",
if (true == is_explicit_mapping) {
fprintf(fp, ".%s(",
output_port[0]->prefix);
}
fprintf(fp, "%s__%s_%d_",
des_pin_prefix, des_pb_graph_pin->port->name, des_pb_graph_pin->pin_number);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
/* Middle output for wires in logic blocks: TODO: Abolish to save simulation time */
/* fprintf(fp, "gidle_mid_out "); */
/* Local vdd and gnd, TODO: we should have an independent VDD for all local interconnections*/
@ -1257,19 +1278,35 @@ void dump_verilog_pb_graph_pin_interc(t_sram_orgz_info* cur_sram_orgz_info,
fprintf(fp, "%s_size%d ", cur_interc->spice_model->name, fan_in);
fprintf(fp, "%s_size%d_%d_ (", cur_interc->spice_model->prefix, fan_in, cur_interc->spice_model->cnt);
/* Dump global ports */
if (0 < rec_dump_verilog_spice_model_global_ports(fp, cur_interc->spice_model, FALSE, FALSE, FALSE)) {
if (0 < rec_dump_verilog_spice_model_global_ports(fp, cur_interc->spice_model, FALSE, FALSE, my_bool_to_boolean(is_explicit_mapping))) {
fprintf(fp, ",\n");
}
/* Inputs */
fprintf(fp, "in_bus_%s_size%d_%d_, ",
if (true == is_explicit_mapping) {
fprintf(fp, ".%s(",
input_port[0]->prefix);
}
fprintf(fp, "in_bus_%s_size%d_%d_",
cur_interc->spice_model->name, fan_in, cur_interc->spice_model->cnt);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
fprintf(fp, ", ");
/* Generate the pin_prefix for src_pb_graph_node and des_pb_graph_node*/
if (true == is_explicit_mapping) {
fprintf(fp, ".%s(",
output_port[0]->prefix);
}
generate_verilog_src_des_pb_graph_pin_prefix(src_pb_graph_pin, des_pb_graph_pin, pin2pin_interc_type,
cur_interc, formatted_parent_pin_prefix, &src_pin_prefix, &des_pin_prefix);
des_pin_prefix = chomp_verilog_prefix(des_pin_prefix);
/* Outputs */
fprintf(fp, "%s__%s_%d_, ",
fprintf(fp, "%s__%s_%d_",
des_pin_prefix, des_pb_graph_pin->port->name, des_pb_graph_pin->pin_number);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
fprintf(fp, ", ");
/* Different design technology requires different configuration bus! */
dump_verilog_mux_config_bus_ports(fp, cur_interc->spice_model, cur_sram_orgz_info,
@ -1853,13 +1890,8 @@ void dump_verilog_phy_pb_graph_node_rec(t_sram_orgz_info* cur_sram_orgz_info,
/* Print inputs, outputs, inouts, clocks
* NO SRAMs !!! They have already been fixed in the bottom level
*/
bool is_explicit_full_name = true;
if (NULL != cur_pb_type->modes[mode_index].pb_type_children[ipb].spice_model){
/*if (SPICE_MODEL_HARDLOGIC == cur_pb_type->modes[mode_index].pb_type_children[ipb].spice_model->type){
is_explicit_full_name = false;
}TEST*/
}
dump_verilog_pb_type_ports(fp, child_pb_type_prefix, 0, &(cur_pb_type->modes[mode_index].pb_type_children[ipb]), FALSE, FALSE, my_bool_to_boolean(is_explicit_mapping), is_explicit_full_name);
//}
dump_verilog_pb_type_ports(fp, child_pb_type_prefix, 0, &(cur_pb_type->modes[mode_index].pb_type_children[ipb]), FALSE, FALSE, my_bool_to_boolean(is_explicit_mapping), true);
/* Print I/O pads */
dump_verilog_grid_common_port(fp, iopad_verilog_model,
gio_inout_prefix,
@ -1906,7 +1938,7 @@ void dump_verilog_phy_pb_graph_node_rec(t_sram_orgz_info* cur_sram_orgz_info,
/* Print interconnections, set is_idle as TRUE*/
dump_verilog_pb_graph_interc(cur_sram_orgz_info, fp, subckt_name,
cur_pb_graph_node, mode_index,
false);
is_explicit_mapping);
/* Check each pins of pb_graph_node */
/* Check and update stamped_sram_cnt */
/* Now we only dump one Verilog for each pb_type, and instance them when num_pb > 1

View File

@ -184,7 +184,6 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
dump_verilog_sram_config_bus_internal_wires(fp, cur_sram_orgz_info,
cur_num_sram, cur_num_sram + num_sram - 1);
}
if (0 < num_sram_port) {
switch (cur_sram_orgz_info->type) {
case SPICE_SRAM_MEMORY_BANK:
@ -234,6 +233,7 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
/* Only dump the global ports belonging to a spice_model
* Disable recursive here !
*/
/*if (0 < rec_dump_verilog_spice_model_global_ports(fp, verilog_model, FALSE, FALSE, my_bool_to_boolean(is_explicit_mapping))) {*/
if (0 < rec_dump_verilog_spice_model_global_ports(fp, verilog_model, FALSE, FALSE, subckt_require_explicit_port_map)) {
fprintf(fp, ",\n");
}
@ -243,6 +243,7 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
/* print ports --> input ports */
dump_verilog_pb_type_bus_ports(fp, port_prefix, 1, prim_pb_type, FALSE, FALSE,
subckt_require_explicit_port_map);
/* my_bool_to_boolean(is_explicit_mapping));*/
/* IOPADs requires a specical port to output */
if (SPICE_MODEL_IOPAD == verilog_model->type) {
fprintf(fp, ",\n");
@ -250,13 +251,15 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
assert(NULL != pad_ports[0]);
/* Add explicit port mapping if required */
if (TRUE == subckt_require_explicit_port_map) {
fprintf(fp, ".%s(",
/*if (true == is_explicit_mapping) {*/
fprintf(fp, ".%s (",
pad_ports[0]->lib_name);
}
/* Print inout port */
fprintf(fp, "%s%s[%d]", gio_inout_prefix,
verilog_model->prefix, verilog_model->cnt);
if (TRUE == subckt_require_explicit_port_map) {
/*if (true == is_explicit_mapping) {*/
fprintf(fp, ")");
}
fprintf(fp, ", ");
@ -273,7 +276,7 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
&& (TRUE == subckt_require_explicit_port_map)) {
assert( 1 == num_sram_port);
assert( NULL != sram_ports[0]);
fprintf(fp, ".%s(",
fprintf(fp, ".%s (",
sram_ports[0]->lib_name);
}
dump_verilog_sram_one_local_outport(fp, cur_sram_orgz_info,
@ -294,14 +297,14 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
&& (TRUE == subckt_require_explicit_port_map)) {
assert( 1 == num_sram_port);
assert( NULL != sram_ports[0]);
fprintf(fp, ".%s(",
fprintf(fp, ".%s (",
sram_ports[0]->inv_prefix);
}
dump_verilog_sram_one_local_outport(fp, cur_sram_orgz_info,
cur_num_sram, cur_num_sram + num_sram - 1,
1, VERILOG_PORT_CONKT);
if ( (0 < num_sram)
&& (TRUE == verilog_model->dump_explicit_port_map || is_explicit_mapping)) {
&& (TRUE == subckt_require_explicit_port_map)) {
fprintf(fp, ")");
}
break;
@ -311,7 +314,7 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
&& (TRUE == subckt_require_explicit_port_map)) {
assert( 1 == num_sram_port);
assert( NULL != sram_ports[0]);
fprintf(fp, ".%s(",
fprintf(fp, ".%s (",
sram_ports[0]->lib_name);
}
dump_verilog_sram_one_outport(fp, cur_sram_orgz_info,
@ -331,7 +334,7 @@ void dump_verilog_pb_generic_primitive(t_sram_orgz_info* cur_sram_orgz_info,
&& (TRUE == subckt_require_explicit_port_map)) {
assert( 1 == num_sram_port);
assert( NULL != sram_ports[0]);
fprintf(fp, ".%s(",
fprintf(fp, ".%s (",
sram_ports[0]->inv_prefix);
}
dump_verilog_sram_one_outport(fp, cur_sram_orgz_info,

View File

@ -2740,6 +2740,9 @@ void verilog_generate_routing_wire_report_timing(t_trpt_opts trpt_opts,
vpr_printf(TIO_MESSAGE_INFO,
"Generating TCL script to report timing for routing wires\n");
vpr_printf(TIO_MESSAGE_INFO,
"Generating TCL script to report timing for routing wires horizontal\n");
/* Start with horizontal SBs*/
/* We start from a SB[x][y] */
DeviceCoordinator sb_range = device_rr_gsb.get_gsb_range();
for (size_t ix = 0; ix < sb_range.get_x(); ++ix) {
@ -2759,6 +2762,9 @@ void verilog_generate_routing_wire_report_timing(t_trpt_opts trpt_opts,
if (1 == rr_sb.get_chan_node(side_manager.get_side(), itrack)->num_drive_rr_nodes) {
continue;
}
if (CHANY == rr_sb.get_chan_node(side_manager.get_side(), itrack)->type) {
continue;
}
/* Check if L_wire exists in the linked list */
L_wire = get_rr_node_wire_length(rr_sb.get_chan_node(side_manager.get_side(), itrack));
/* Get counter */
@ -2793,6 +2799,72 @@ void verilog_generate_routing_wire_report_timing(t_trpt_opts trpt_opts,
}
}
/* close file*/
fclose_wire_L_file_handler_in_llist(rr_path_cnt);
/* Need to reset the different variables */
rr_path_cnt = NULL;
wireL_cnt = NULL;
path_cnt = 0;
vpr_printf(TIO_MESSAGE_INFO,
"Generating TCL script to report timing for routing wires vertical\n");
/* Continue with vertical SBs*/
/* We start from a SB[x][y] */
for (size_t ix = 0; ix < sb_range.get_x(); ++ix) {
for (size_t iy = 0; iy < sb_range.get_y(); ++iy) {
const RRGSB& rr_sb = device_rr_gsb.get_gsb(ix, iy);
for (size_t side = 0; side < rr_sb.get_num_sides(); ++side) {
Side side_manager(side);
for (size_t itrack = 0; itrack < rr_sb.get_chan_width(side_manager.get_side()); ++itrack) {
assert((CHANX == rr_sb.get_chan_node(side_manager.get_side(), itrack)->type)
||(CHANY == rr_sb.get_chan_node(side_manager.get_side(), itrack)->type));
/* We only care the output port and it should indicate a SB mux */
if ( (OUT_PORT != rr_sb.get_chan_node_direction(side_manager.get_side(), itrack))
|| (false != rr_sb.is_sb_node_passing_wire(side_manager.get_side(), itrack))) {
continue;
}
/* Bypass if we have only 1 driving node */
if (1 == rr_sb.get_chan_node(side_manager.get_side(), itrack)->num_drive_rr_nodes) {
continue;
}
if (CHANX == rr_sb.get_chan_node(side_manager.get_side(), itrack)->type) {
continue;
}
/* Check if L_wire exists in the linked list */
L_wire = get_rr_node_wire_length(rr_sb.get_chan_node(side_manager.get_side(), itrack));
/* Get counter */
rr_path_cnt = get_wire_L_counter_in_llist(rr_path_cnt, trpt_opts, "vertical", L_wire, &wireL_cnt);
path_cnt = wireL_cnt->cnt;
fp = wireL_cnt->file_handler;
/* This is a new L-wire, create the file handler and the mkdir command to the TCL script */
if (0 == path_cnt) {
fprintf(fp, "exec mkdir -p %s\n",
gen_verilog_one_routing_report_timing_Lwire_dir_path(fpga_verilog_opts.report_timing_path, L_wire));
}
/* Restore the disable_timing for the SB outputs on the path */
/*fprintf(fp, "# Restore disable timing for the following Switch Block output:\n");
restore_disable_timing_one_sb_output(fp,
rr_sb,
rr_sb.get_chan_node(side_manager.get_side(), itrack));*/
fprintf(fp, "# Report timing for all the paths using this output:\n");
/* Dump report_timing command */
verilog_generate_one_routing_segmental_report_timing(fp, fpga_verilog_opts,
rr_sb,
side_manager.get_side(), itrack,
LL_rr_node, "vertical", &path_cnt);
/* Disable the timing again */
/*fprintf(fp, "# Set disable timing for the following Switch Block output:\n");
set_disable_timing_one_sb_output(fp,
rr_sb,
rr_sb.get_chan_node(side_manager.get_side(), itrack));*/
/* Update the wire L*/
update_wire_L_counter_in_llist(rr_path_cnt, L_wire, path_cnt);
}
}
}
}
/* close file*/
fclose_wire_L_file_handler_in_llist(rr_path_cnt);

View File

@ -981,6 +981,7 @@ void dump_verilog_unique_switch_box_mux(t_sram_orgz_info* cur_sram_orgz_info,
int cur_bl, cur_wl;
t_spice_model* mem_model = NULL;
char* mem_subckt_name = NULL;
int num_input_port, num_output_port, num_sram_port;
/* Check the file handler*/
if (NULL == fp) {
@ -1096,8 +1097,11 @@ void dump_verilog_unique_switch_box_mux(t_sram_orgz_info* cur_sram_orgz_info,
fprintf(fp, ",\n");
}
t_spice_model_port** input_port = find_spice_model_ports(verilog_model, SPICE_MODEL_PORT_INPUT, &num_input_port, TRUE);
t_spice_model_port** output_port = find_spice_model_ports(verilog_model, SPICE_MODEL_PORT_OUTPUT, &num_output_port, TRUE);
if (TRUE == is_explicit_mapping) {
fprintf(fp, ".in(");
fprintf(fp, ".%s(",
input_port[0]->prefix);
fprintf(fp, "%s_size%d_%d_inbus), ",
verilog_model->prefix, mux_size, verilog_model->cnt);
}
@ -1107,7 +1111,8 @@ void dump_verilog_unique_switch_box_mux(t_sram_orgz_info* cur_sram_orgz_info,
}
/* Output port */
if (TRUE == is_explicit_mapping) {
fprintf(fp, ".out(");
fprintf(fp, ".%s(",
output_port[0]->prefix);
dump_verilog_unique_switch_box_chan_port(fp, rr_sb, chan_side, cur_rr_node, OUT_PORT);
fprintf(fp, ")");
}
@ -1453,6 +1458,10 @@ void dump_verilog_unique_switch_box_interc(t_sram_orgz_info* cur_sram_orgz_info,
} else {
num_drive_rr_nodes = cur_rr_node->num_drive_rr_nodes;
drive_rr_nodes = cur_rr_node->drive_rr_nodes;
/* Special: if there are zero-driver nodes. We skip here */
if (0 == num_drive_rr_nodes) {
return;
}
}
if (0 == num_drive_rr_nodes) {

View File

@ -2732,12 +2732,13 @@ void verilog_generate_sdc_pnr(t_sram_orgz_info* cur_sram_orgz_info,
}
/* Part 5. Output routing constraints for Connection Blocks */
if (TRUE == sdc_opts.constrain_routing_channels) {
/* BC: Might not be useful as it constrains nets which are assigned too*/
/*if (TRUE == sdc_opts.constrain_routing_channels) {
verilog_generate_sdc_constrain_routing_channels(sdc_opts, arch,
LL_nx, LL_ny,
LL_num_rr_nodes, LL_rr_node,
LL_rr_node_indices, LL_rr_indexed_data);
}
}*/
/* Part 6. Output routing constraints for Programmable blocks */
if (TRUE == sdc_opts.constrain_pbs) {

View File

@ -722,8 +722,10 @@ void dump_verilog_cmos_mux_one_basis_module_structural(FILE* fp,
t_spice_model* tgate_spice_model = cur_spice_model->pass_gate_logic->spice_model;
int num_input_port = 0;
int num_output_port = 0;
int num_sram_port = 0;
t_spice_model_port** input_port = NULL;
t_spice_model_port** output_port = NULL;
t_spice_model_port** sram_port = NULL;
assert(TRUE == cur_spice_model->dump_structural_verilog);
@ -737,6 +739,7 @@ void dump_verilog_cmos_mux_one_basis_module_structural(FILE* fp,
assert ( NULL != tgate_spice_model);
input_port = find_spice_model_ports(tgate_spice_model, SPICE_MODEL_PORT_INPUT, &num_input_port, TRUE);
output_port = find_spice_model_ports(tgate_spice_model, SPICE_MODEL_PORT_OUTPUT, &num_output_port, TRUE);
sram_port = find_spice_model_ports(tgate_spice_model, SPICE_MODEL_PORT_SRAM, &num_sram_port, TRUE);
/* Check */
assert ((3 == num_input_port));
@ -764,9 +767,9 @@ void dump_verilog_cmos_mux_one_basis_module_structural(FILE* fp,
fprintf(fp, "input [0:%d] in,\n", num_input_basis_subckt - 1);
fprintf(fp, "output out,\n");
fprintf(fp, "input [0:%d] mem,\n",
num_mem - 1);
num_mem - 1/*, sram_port[0]->prefix*/);
fprintf(fp, "input [0:%d] mem_inv);\n",
num_mem - 1);
num_mem - 1/*, sram_port[0]->prefix*/);
/* Verilog Behavior description for a MUX */
fprintf(fp, "//---- Structure-level description -----\n");
/* Special case: only one memory, switch case is simpler
@ -1678,7 +1681,8 @@ void dump_verilog_cmos_mux_submodule(FILE* fp,
switch (cur_mux_structure) {
case SPICE_MODEL_STRUCTURE_TREE:
dump_verilog_cmos_mux_tree_structure(fp, mux_basis_subckt_name,
spice_model, spice_mux_arch, num_sram_port, sram_port, is_explicit_mapping);
spice_model, spice_mux_arch,
num_sram_port, sram_port, is_explicit_mapping);
break;
case SPICE_MODEL_STRUCTURE_ONELEVEL:
dump_verilog_cmos_mux_onelevel_structure(fp, mux_basis_subckt_name,

View File

@ -1069,7 +1069,8 @@ void dump_verilog_configuration_circuits_standalone_srams(t_sram_orgz_info* cur_
*/
static
void dump_verilog_configuration_circuits_scan_chains(t_sram_orgz_info* cur_sram_orgz_info,
FILE* fp) {
FILE* fp,
bool is_explicit_mapping) {
int num_mem_bits = 0;
/* Check */
@ -1088,12 +1089,31 @@ void dump_verilog_configuration_circuits_scan_chains(t_sram_orgz_info* cur_sram_
verilog_config_peripheral_prefix,
verilog_config_peripheral_prefix);
/* Scan-chain input*/
if (true == is_explicit_mapping) {
fprintf(fp, ".%s (",
top_netlist_scan_chain_head_prefix);
}
dump_verilog_generic_port(fp, VERILOG_PORT_CONKT,
top_netlist_scan_chain_head_prefix, 0, 0);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
fprintf(fp, ",\n");
if (true == is_explicit_mapping) {
fprintf(fp, ".scff_scff_in_local_bus (");
}
dump_verilog_sram_one_local_outport(fp, cur_sram_orgz_info, 0, num_mem_bits - 1, -1, VERILOG_PORT_CONKT);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
fprintf(fp, ",\n");
if (true == is_explicit_mapping) {
fprintf(fp, ".scff_scff_out_local_bus (");
}
dump_verilog_sram_one_local_outport(fp, cur_sram_orgz_info, 0, num_mem_bits - 1, 0, VERILOG_PORT_CONKT);
if (true == is_explicit_mapping) {
fprintf(fp, ")");
}
fprintf(fp, ");\n");
fprintf(fp, "//------ END Configuration peripheral Scan-chain FFs -----\n");
@ -1103,7 +1123,8 @@ void dump_verilog_configuration_circuits_scan_chains(t_sram_orgz_info* cur_sram_
/* Dump a memory bank to configure all the Bit lines and Word lines */
static
void dump_verilog_configuration_circuits_memory_bank(FILE* fp,
t_sram_orgz_info* cur_sram_orgz_info) {
t_sram_orgz_info* cur_sram_orgz_info,
bool is_explicit_mapping) {
int num_bl, num_wl;
int num_reserved_bl, num_reserved_wl;
int num_array_bl, num_array_wl;
@ -1210,16 +1231,18 @@ void dump_verilog_configuration_circuits_memory_bank(FILE* fp,
* 3. Standalone SRAMs
*/
void dump_verilog_configuration_circuits(t_sram_orgz_info* cur_sram_orgz_info,
FILE* fp) {
FILE* fp,
bool is_explicit_mapping) {
switch(cur_sram_orgz_info->type) {
case SPICE_SRAM_STANDALONE:
dump_verilog_configuration_circuits_standalone_srams(cur_sram_orgz_info, fp);
break;
case SPICE_SRAM_SCAN_CHAIN:
dump_verilog_configuration_circuits_scan_chains(cur_sram_orgz_info, fp);
dump_verilog_configuration_circuits_scan_chains(cur_sram_orgz_info, fp, is_explicit_mapping);
break;
case SPICE_SRAM_MEMORY_BANK:
dump_verilog_configuration_circuits_memory_bank(fp, cur_sram_orgz_info);
/* BC: TODO explicit_mapping*/
dump_verilog_configuration_circuits_memory_bank(fp, cur_sram_orgz_info, is_explicit_mapping);
break;
default:
vpr_printf(TIO_MESSAGE_ERROR,"(File:%s,[LINE%d])Invalid type of SRAM organization in Verilog Generator!\n",

View File

@ -24,7 +24,8 @@ void dump_verilog_clb2clb_directs(FILE* fp,
int num_directs, t_clb_to_clb_directs* direct);
void dump_verilog_configuration_circuits(t_sram_orgz_info* cur_sram_orgz_info,
FILE* fp);
FILE* fp,
bool is_explicit_mapping);
void dump_verilog_top_module_ports(t_sram_orgz_info* cur_sram_orgz_info,
FILE* fp,

View File

@ -902,8 +902,8 @@ int rec_dump_verilog_spice_model_global_ports(FILE* fp,
/* Add explicit port mapping if required */
if (TRUE == require_explicit_port_map ) {
fprintf(fp, ".%s(",
cur_spice_model_port->lib_name);
/*cur_spice_model_port->prefix);*/
cur_spice_model_port->lib_name);
//cur_spice_model_port->prefix);
}
fprintf(fp, "%s[0:%d]",
cur_spice_model_port->prefix,
@ -2575,6 +2575,8 @@ void dump_verilog_cmos_mux_config_bus_ports(FILE* fp, t_spice_model* mux_spice_m
int num_mux_reserved_conf_bits,
int num_mux_conf_bits,
bool is_explicit_mapping) {
int num_sram_port;
t_spice_model_port** sram_port = find_spice_model_ports(mux_spice_model, SPICE_MODEL_PORT_SRAM, &num_sram_port, TRUE);
/* Check the file handler*/
if (NULL == fp) {
vpr_printf(TIO_MESSAGE_ERROR,"(File:%s,[LINE%d])Invalid file handler.\n",
@ -2595,7 +2597,8 @@ void dump_verilog_cmos_mux_config_bus_ports(FILE* fp, t_spice_model* mux_spice_m
* We do not need a prefix implying MUX name, size and index
*/
if (true == is_explicit_mapping) {
fprintf(fp, ".sram(");
fprintf(fp, ".%s (",
sram_port[0]->prefix);
}
dump_verilog_mux_sram_one_outport(fp, cur_sram_orgz_info,
mux_spice_model, mux_size,
@ -2607,7 +2610,8 @@ void dump_verilog_cmos_mux_config_bus_ports(FILE* fp, t_spice_model* mux_spice_m
}
fprintf(fp, ", ");
if (TRUE == is_explicit_mapping) {
fprintf(fp, ".sram_inv(");
fprintf(fp, ".%s_inv (",
sram_port[0]->prefix);
}
dump_verilog_mux_sram_one_outport(fp, cur_sram_orgz_info,
mux_spice_model, mux_size,
@ -2624,7 +2628,8 @@ void dump_verilog_cmos_mux_config_bus_ports(FILE* fp, t_spice_model* mux_spice_m
* We need a prefix implying MUX name, size and index
*/
if (TRUE == is_explicit_mapping) {
fprintf(fp, ".sram(");
fprintf(fp, ".%s (",
sram_port[0]->prefix);
}
dump_verilog_mux_sram_one_outport(fp, cur_sram_orgz_info,
mux_spice_model, mux_size,
@ -2636,7 +2641,8 @@ void dump_verilog_cmos_mux_config_bus_ports(FILE* fp, t_spice_model* mux_spice_m
}
fprintf(fp, ",\n");
if (TRUE == is_explicit_mapping) {
fprintf(fp, ".sram_inv(");
fprintf(fp, ".%s_inv (",
sram_port[0]->prefix);
}
dump_verilog_mux_sram_one_outport(fp, cur_sram_orgz_info,
mux_spice_model, mux_size,
@ -3102,6 +3108,7 @@ void dump_verilog_mem_sram_submodule(FILE* fp,
int num_bl_per_sram = 0;
int num_wl_per_sram = 0;
int iport = 0;
t_llist* spice_model_head = NULL;
/* Check the file handler*/
if (NULL == fp) {
@ -3198,7 +3205,11 @@ void dump_verilog_mem_sram_submodule(FILE* fp,
break;
case SPICE_SRAM_SCAN_CHAIN:
/* Only dump the global ports belonging to a spice_model */
if (0 < rec_dump_verilog_spice_model_global_ports(fp, cur_sram_verilog_model, FALSE, TRUE, my_bool_to_boolean(is_explicit_mapping))) {
rec_stats_spice_model_global_ports(cur_sram_verilog_model,
TRUE,
&spice_model_head);
if (0 < dump_verilog_global_ports( fp, spice_model_head, FALSE, is_explicit_mapping)) {
//if (0 < rec_dump_verilog_spice_model_global_ports(fp, cur_sram_verilog_model, FALSE, TRUE, FALSE)) {
fprintf(fp, ",\n");
}
if (SPICE_MODEL_MUX == cur_verilog_model->type) {

View File

@ -25,7 +25,7 @@ arch_ff_keyword="FFPATHKEYWORD"
# Remove previous designs
rm -rf $verilog_output_dirpath/$verilog_output_dirname
mkdir ${OpenFPGA_path}/fpga_flow/arch/generated
mkdir -p ${OpenFPGA_path}/fpga_flow/arch/generated
cd $fpga_flow_scripts
perl rewrite_path_in_file.pl -i $template_arch_xml_file -o $arch_xml_file
@ -33,7 +33,8 @@ perl rewrite_path_in_file.pl -i $arch_xml_file -k $arch_ff_keyword $new_ff_path
cd -
# Run VPR
./vpr $arch_xml_file $blif_file --full_stats --nodisp --activity_file $act_file --fpga_verilog --fpga_verilog_dir $verilog_output_dirpath/$verilog_output_dirname --fpga_x2p_rename_illegal_port --fpga_bitstream_generator --fpga_verilog_print_top_testbench --fpga_verilog_print_input_blif_testbench --fpga_verilog_include_timing --fpga_verilog_include_signal_init --fpga_verilog_print_formal_verification_top_netlist --fpga_verilog_print_autocheck_top_testbench $verilog_reference --fpga_verilog_print_user_defined_template --route_chan_width $vpr_route_chan_width --fpga_verilog_include_icarus_simulator --fpga_verilog_print_report_timing_tcl --power --tech_properties $tech_file --fpga_verilog_print_sdc_pnr --fpga_verilog_print_sdc_analysis --fpga_x2p_compact_routing_hierarchy --fpga_verilog_explicit_mapping
#echo "./vpr $arch_xml_file $blif_file --full_stats --nodisp --activity_file $act_file --fpga_verilog --fpga_verilog_dir $verilog_output_dirpath/$verilog_output_dirname --fpga_x2p_rename_illegal_port --fpga_bitstream_generator --fpga_verilog_print_top_testbench --fpga_verilog_print_input_blif_testbench --fpga_verilog_include_timing --fpga_verilog_include_signal_init --fpga_verilog_print_formal_verification_top_netlist --fpga_verilog_print_autocheck_top_testbench $verilog_reference --fpga_verilog_print_user_defined_template --route_chan_width $vpr_route_chan_width --fpga_verilog_include_icarus_simulator --fpga_verilog_print_report_timing_tcl --power --tech_properties $tech_file --fpga_verilog_print_sdc_pnr --fpga_verilog_print_sdc_analysis --fpga_x2p_compact_routing_hierarchy #--fpga_verilog_explicit_mapping"
./vpr $arch_xml_file $blif_file --full_stats --nodisp --activity_file $act_file --fpga_verilog --fpga_verilog_dir $verilog_output_dirpath/$verilog_output_dirname --fpga_x2p_rename_illegal_port --fpga_bitstream_generator --fpga_verilog_print_top_testbench --fpga_verilog_print_input_blif_testbench --fpga_verilog_include_timing --fpga_verilog_include_signal_init --fpga_verilog_print_formal_verification_top_netlist --fpga_verilog_print_autocheck_top_testbench $verilog_reference --fpga_verilog_print_user_defined_template --route_chan_width $vpr_route_chan_width --fpga_verilog_include_icarus_simulator --fpga_verilog_print_report_timing_tcl --power --tech_properties $tech_file --fpga_verilog_print_sdc_pnr --fpga_verilog_print_sdc_analysis --fpga_x2p_compact_routing_hierarchy #--fpga_verilog_explicit_mapping
cd $fpga_flow_scripts
perl rewrite_path_in_file.pl -i $ff_path -o $new_ff_path -k $ff_keyword $ff_include_path