Xilinx report

VHDL implementation of a multisensor receiver

prepared by P. Bakowski

This pages contain the report generated by Xilinx tools for the implementation of the circuit in XC3000 FPGA.

PPR RESULTS FOR DESIGN LMS_FINAL_P
From PPR Version 5.2.0
1997/06/19 12:25:18
Xilinx, Inc.
(c) Copyright 1997. All Rights Reserved.
Table of Contents
-----------------
List of Warnings ................................................. 1
Device Utilization ............................................... 2
Implementation Options ........................................... 3
Xact Performance Summary ......................................... 4
Chip Pinout Description .......................................... 5
Routing Summary .................................................. 12
Information in Other Reports ..................................... 21
List of Warnings
----------------
*** PPR: WARNING 5527:
The design uses no global buffers (BUFGS or BUFGP). Their use can
improve performance for clocks or widely distributed signals.
*** PPR: WARNING 7028:
The design has flip-flops with asynchronous set/reset controls (PRE/SD
or CLR/RD pins). When PPR analyzes design timing, it does not trace
paths through the asynchronous set/reset input and on through the Q
output.
If you want PPR to control the delay on paths through asynchronous
set/reset pins, you must split the delay requirement into two
segments: one ending at the set/reset input, and the other beginning
at the flip-flop output.
If you want PPR not to analyze paths that lead to asynchronous
set/reset pins, attach an IGNORE specification to the pin(s) or
signal(s).
By default, XDelay reports all paths through asynchronous set/reset
pins. To prevent XDelay from showing these paths, use FlagBlk
CLB_Disable_SR_Q on the appropriate flip-flops.
Device Utilization
------------------
Partitioned Design Utilization Using Part 4013PG223-3
-----------------------------------------------------------------
No. Used Max Available %Used
-----------------------------------------------------------------
Occupied CLBs 576 576 100%
Bonded I/O Pins 110 192 57%
F and G Function Generators (*) 1142 1152 99%
H Function Generators 61 576 10%
CLB Flip Flops 419 1152 36%
IOB Input Flip Flops 0 192 0%
IOB Output Flip Flops 0 192 0%
3-State Buffers 0 1248 0%
3-State Half Longlines 0 96 0%
Edge Decode Inputs 0 288 0%
Edge Decode Half Longlines 0 32 0%
(*) If RAM/ROM elements are present in the design, this count
includes the function generators used for them. A 16x1 memory uses 1
function generator; a 32x1 uses two.
----------------------------------------------------------------
CPU Times
CPU time taken for Partition: 0 hrs 2 mins 29 secs
CPU time taken for Placement: 0 hrs 29 mins 11 secs
Implementation Options
----------------------
PPR Parameters
Design = lms_final_p.xtf
Logfile = ppr.log
Outfile =
Estimate = FALSE
Additional Specified or Non-Default Parameters
parttype = 4013PG223-3
cstfile = lms_final_p
seed = 866719192
Xact Performance Summary
------------------------
Parttype Used : 4013PG223
Speed Grade : -3
End-
Limit Actual Points
(ns) * (ns) Missed Specification
------ ------ ------- -------------
127.7 0/823 DEFAULT_FROM_FFS_TO_FFS=FROM:ffs:TO:ffs
34.5 0/882 DEFAULT_FROM_PADS_TO_FFS=FROM:pads:TO:ffs
17.4 0/48 DEFAULT_FROM_FFS_TO_PADS=FROM:ffs:TO:pads
(*) Use the -FailedSpec and/or -TSMaxPaths options of the
XDelay-TimeSpec command, accessible through the XDE or XDelay program,
to confirm the actual path delays computed by PPR. Note that
XDelay-TimeSpec will not report paths that start and end in the same
block (CLB or IOB) and use no external routing.
*** PPR: WARNING 7028:
The design has flip-flops with asynchronous set/reset controls (PRE/SD
or CLR/RD pins). When PPR analyzes design timing, it does not trace
paths through the asynchronous set/reset input and on through the Q
output.
If you want PPR to control the delay on paths through asynchronous
set/reset pins, you must split the delay requirement into two
segments: one ending at the set/reset input, and the other beginning
at the flip-flop output. If you want PPR not to analyze paths that
lead to asynchronous set/reset pins, attach an IGNORE specification to
the pin(s) or signal(s).
By default, XDelay reports all paths through asynchronous set/reset
pins. To prevent XDelay from showing these paths, use FlagBlk
CLB_Disable_SR_Q on the appropriate flip-flops.
Chip Pinout Description
-----------------------
This chapter describes where your design's pins were placed in termsof the package pins. Generally there are four sections for this chapter.
The first section is a list showing signal name and the package pin location, sorted by the signal name.
The second section is a list showing the package pin names and signal names sorted by the
package pin names.
Next section appears only if your design uses special pads.
This will a table showing the special pad names and the
signal names, sorted by special pad name.
The last section is a series of CST file statements, which if copied into a text file, can be used
as constraints for a subsequent ppr run for locking IOs at their current locations.
Sorted by Signal Names:
Pin Name Package Pin Location
-------- --------------------
CLK : A10
ENTREE_1<0> : K1
ENTREE_1<1> : L1
ENTREE_1<2> : N1
ENTREE_1<3> : P1
ENTREE_1<4> : R1
ENTREE_1<5> : T1
ENTREE_1<6> : L2
ENTREE_1<7> : N2
ENTREE_2<0> : P2
ENTREE_2<1> : R2
ENTREE_2<2> : L3
ENTREE_2<3> : P3
ENTREE_2<4> : C9
ENTREE_2<5> : C10
ENTREE_2<6> : L4
ENTREE_2<7> : M4
ENTREE_3<0> : N4
ENTREE_3<1> : P4
ENTREE_3<2> : U4
ENTREE_3<3> : V4
ENTREE_3<4> : R5
ENTREE_3<5> : T5
ENTREE_3<6> : U5
ENTREE_3<7> : V5
ENTREE_4<0> : R6
ENTREE_4<1> : T6
ENTREE_4<2> : U6
ENTREE_4<3> : V6
ENTREE_4<4> : R8
ENTREE_4<5> : T8
ENTREE_4<6> : U8
ENTREE_4<7> : V8
ENTREE_5<0> : V9
ENTREE_5<1> : T10
ENTREE_5<2> : R11
ENTREE_5<3> : T11
ENTREE_5<4> : U11
ENTREE_5<5> : V11
ENTREE_5<6> : R12
ENTREE_5<7> : R13

Pin Name Package Pin Location (continued)
-------- --------------------
ENTREE_6<0> : B1
ENTREE_6<1> : C1
ENTREE_6<2> : D1
ENTREE_6<3> : E1
ENTREE_6<4> : F1
ENTREE_6<5> : H1
ENTREE_6<6> : J1
ENTREE_6<7> : E2
ENTREE_7<0> : E3
ENTREE_7<1> : F3
ENTREE_7<2> : H3
ENTREE_7<3> : A4
ENTREE_7<4> : E4
ENTREE_7<5> : F4
ENTREE_7<6> : G4
ENTREE_7<7> : H4
ENTREE_7<8> : J3
ENTREE_7<9> : A5
ENTREE_7<10> : B5
ENTREE_7<11> : C5
RESET<0> : C11
SORTIE_1<0> : B18
SORTIE_1<1> : C18
SORTIE_1<2> : D18
SORTIE_1<3> : E18
SORTIE_1<4> : F18
SORTIE_1<5> : G18
SORTIE_1<6> : H18
SORTIE_1<7> : J18
SORTIE_1<8> : A17
SORTIE_1<9> : C17
SORTIE_1<10> : D17
SORTIE_1<11> : F17
SORTIE_2<0> : A16
SORTIE_2<1> : A15
SORTIE_2<2> : A14
SORTIE_2<3> : A13
SORTIE_2<4> : A12
SORTIE_2<5> : A11
SORTIE_2<6> : B9
SORTIE_2<7> : B10
SORTIE_2<8> : B11
SORTIE_2<9> : B12
SORTIE_2<10> : B13
SORTIE_2<11> : B14
SORTIE_3<0> : K18
SORTIE_3<1> : L18
SORTIE_3<2> : M18
SORTIE_3<3> : N18
SORTIE_3<4> : P18
SORTIE_3<5> : R18
SORTIE_3<6> : T18
SORTIE_3<7> : U18
SORTIE_3<8> : J17
SORTIE_3<9> : K17
SORTIE_3<10> : L17
SORTIE_3<11> : M17
SORTIE_4<0> : N17
PPR RESULTS FOR DESIGN LMS_FINAL_P Page 7
Pin Name Package Pin Location (continued)
-------- --------------------
SORTIE_4<1> : P17
SORTIE_4<2> : R17
SORTIE_4<3> : T17
SORTIE_4<4> : E15
SORTIE_4<5> : F15
SORTIE_4<6> : G15
SORTIE_4<7> : H15
SORTIE_4<8> : L15
SORTIE_4<9> : M15
SORTIE_4<10> : N15
SORTIE_4<11> : P15
Sorted by Package Pin Locations:
Package Pin Location Pin Name
-------------------- --------
A4 : ENTREE_7<3>
A5 : ENTREE_7<9>
A10 : CLK
A11 : SORTIE_2<5>
A12 : SORTIE_2<4>
A13 : SORTIE_2<3>
A14 : SORTIE_2<2>
A15 : SORTIE_2<1>
A16 : SORTIE_2<0>
A17 : SORTIE_1<8>
B1 : ENTREE_6<0>
B5 : ENTREE_7<10>
B9 : SORTIE_2<6>
B10 : SORTIE_2<7>
B11 : SORTIE_2<8>
B12 : SORTIE_2<9>
B13 : SORTIE_2<10>
B14 : SORTIE_2<11>
B18 : SORTIE_1<0>
C1 : ENTREE_6<1>
C5 : ENTREE_7<11>
C9 : ENTREE_2<4>
C10 : ENTREE_2<5>
C11 : RESET<0>
C17 : SORTIE_1<9>
C18 : SORTIE_1<1>
D1 : ENTREE_6<2>
D17 : SORTIE_1<10>
D18 : SORTIE_1<2>
E1 : ENTREE_6<3>
E2 : ENTREE_6<7>
E3 : ENTREE_7<0>
E4 : ENTREE_7<4>
E15 : SORTIE_4<4>
E18 : SORTIE_1<3>
F1 : ENTREE_6<4>
F3 : ENTREE_7<1>
F4 : ENTREE_7<5>
F15 : SORTIE_4<5>
F17 : SORTIE_1<11>
F18 : SORTIE_1<4>
G4 : ENTREE_7<6>

Package Pin Location Pin Name (continued)
-------------------- --------
G15 : SORTIE_4<6>
G18 : SORTIE_1<5>
H1 : ENTREE_6<5>
H3 : ENTREE_7<2>
H4 : ENTREE_7<7>
H15 : SORTIE_4<7>
H18 : SORTIE_1<6>
J1 : ENTREE_6<6>
J3 : ENTREE_7<8>
J17 : SORTIE_3<8>
J18 : SORTIE_1<7>
K1 : ENTREE_1<0>
K17 : SORTIE_3<9>
K18 : SORTIE_3<0>
L1 : ENTREE_1<1>
L2 : ENTREE_1<6>
L3 : ENTREE_2<2>
L4 : ENTREE_2<6>
L15 : SORTIE_4<8>
L17 : SORTIE_3<10>
L18 : SORTIE_3<1>
M4 : ENTREE_2<7>
M15 : SORTIE_4<9>
M17 : SORTIE_3<11>
M18 : SORTIE_3<2>
N1 : ENTREE_1<2>
N2 : ENTREE_1<7>
N4 : ENTREE_3<0>
N15 : SORTIE_4<10>
N17 : SORTIE_4<0>
N18 : SORTIE_3<3>
P1 : ENTREE_1<3>
P2 : ENTREE_2<0>
P3 : ENTREE_2<3>
P4 : ENTREE_3<1>
P15 : SORTIE_4<11>
P17 : SORTIE_4<1>
P18 : SORTIE_3<4>
R1 : ENTREE_1<4>
R2 : ENTREE_2<1>
R5 : ENTREE_3<4>
R6 : ENTREE_4<0>
R8 : ENTREE_4<4>
R11 : ENTREE_5<2>
R12 : ENTREE_5<6>
R13 : ENTREE_5<7>
R17 : SORTIE_4<2>
R18 : SORTIE_3<5>
T1 : ENTREE_1<5>
T5 : ENTREE_3<5>
T6 : ENTREE_4<1>
T8 : ENTREE_4<5>
T10 : ENTREE_5<1>
T11 : ENTREE_5<3>
T17 : SORTIE_4<3>
T18 : SORTIE_3<6>
U4 : ENTREE_3<2>
U5 : ENTREE_3<6>

Package Pin Location Pin Name (continued)
-------------------- --------
U6 : ENTREE_4<2>
U8 : ENTREE_4<6>
U11 : ENTREE_5<4>
U18 : SORTIE_3<7>
V4 : ENTREE_3<3>
V5 : ENTREE_3<7>
V6 : ENTREE_4<3>
V8 : ENTREE_4<7>
V9 : ENTREE_5<0>
V11 : ENTREE_5<5>
CST File Format (location constraints file):
place instance clk_pad : A10 ;
place instance entree_1<0>_pad : K1 ;
place instance entree_1<1>_pad : L1 ;
place instance entree_1<2>_pad : N1 ;
place instance entree_1<3>_pad : P1 ;
place instance entree_1<4>_pad : R1 ;
place instance entree_1<5>_pad : T1 ;
place instance entree_1<6>_pad : L2 ;
place instance entree_1<7>_pad : N2 ;
place instance entree_2<0>_pad : P2 ;
place instance entree_2<1>_pad : R2 ;
place instance entree_2<2>_pad : L3 ;
place instance entree_2<3>_pad : P3 ;
place instance entree_2<4>_pad : C9 ;
place instance entree_2<5>_pad : C10 ;
place instance entree_2<6>_pad : L4 ;
place instance entree_2<7>_pad : M4 ;
place instance entree_3<0>_pad : N4 ;
place instance entree_3<1>_pad : P4 ;
place instance entree_3<2>_pad : U4 ;
place instance entree_3<3>_pad : V4 ;
place instance entree_3<4>_pad : R5 ;
place instance entree_3<5>_pad : T5 ;
place instance entree_3<6>_pad : U5 ;
place instance entree_3<7>_pad : V5 ;
place instance entree_4<0>_pad : R6 ;
place instance entree_4<1>_pad : T6 ;
place instance entree_4<2>_pad : U6 ;
place instance entree_4<3>_pad : V6 ;
place instance entree_4<4>_pad : R8 ;
place instance entree_4<5>_pad : T8 ;
place instance entree_4<6>_pad : U8 ;
place instance entree_4<7>_pad : V8 ;
place instance entree_5<0>_pad : V9 ;
place instance entree_5<1>_pad : T10 ;
place instance entree_5<2>_pad : R11 ;
place instance entree_5<3>_pad : T11 ;
place instance entree_5<4>_pad : U11 ;
place instance entree_5<5>_pad : V11 ;
place instance entree_5<6>_pad : R12 ;
place instance entree_5<7>_pad : R13 ;
place instance entree_6<0>_pad : B1 ;
place instance entree_6<1>_pad : C1 ;
place instance entree_6<2>_pad : D1 ;
place instance entree_6<3>_pad : E1 ;
place instance entree_6<4>_pad : F1 ;
place instance entree_6<5>_pad : H1 ;
place instance entree_6<6>_pad : J1 ;
place instance entree_6<7>_pad : E2 ;
place instance entree_7<0>_pad : E3 ;
place instance entree_7<1>_pad : F3 ;
place instance entree_7<2>_pad : H3 ;
place instance entree_7<3>_pad : A4 ;
place instance entree_7<4>_pad : E4 ;
place instance entree_7<5>_pad : F4 ;
place instance entree_7<6>_pad : G4 ;
place instance entree_7<7>_pad : H4 ;
place instance entree_7<8>_pad : J3 ;
place instance entree_7<9>_pad : A5 ;
place instance entree_7<10>_pad : B5 ;
place instance entree_7<11>_pad : C5 ;
place instance reset<0>_pad : C11 ;
place instance sortie_1<0>_pad : B18 ;
place instance sortie_1<1>_pad : C18 ;
place instance sortie_1<2>_pad : D18 ;
place instance sortie_1<3>_pad : E18 ;
place instance sortie_1<4>_pad : F18 ;
place instance sortie_1<5>_pad : G18 ;
place instance sortie_1<6>_pad : H18 ;
place instance sortie_1<7>_pad : J18 ;
place instance sortie_1<8>_pad : A17 ;
place instance sortie_1<9>_pad : C17 ;
place instance sortie_1<10>_pad : D17 ;
place instance sortie_1<11>_pad : F17 ;
place instance sortie_2<0>_pad : A16 ;
place instance sortie_2<1>_pad : A15 ;
place instance sortie_2<2>_pad : A14 ;
place instance sortie_2<3>_pad : A13 ;
place instance sortie_2<4>_pad : A12 ;
place instance sortie_2<5>_pad : A11 ;
place instance sortie_2<6>_pad : B9 ;
place instance sortie_2<7>_pad : B10 ;
place instance sortie_2<8>_pad : B11 ;
place instance sortie_2<9>_pad : B12 ;
place instance sortie_2<10>_pad : B13 ;
place instance sortie_2<11>_pad : B14 ;
place instance sortie_3<0>_pad : K18 ;
place instance sortie_3<1>_pad : L18 ;
place instance sortie_3<2>_pad : M18 ;
place instance sortie_3<3>_pad : N18 ;
place instance sortie_3<4>_pad : P18 ;
place instance sortie_3<5>_pad : R18 ;
place instance sortie_3<6>_pad : T18 ;
place instance sortie_3<7>_pad : U18 ;
place instance sortie_3<8>_pad : J17 ;
place instance sortie_3<9>_pad : K17 ;
place instance sortie_3<10>_pad : L17 ;
place instance sortie_3<11>_pad : M17 ;
place instance sortie_4<0>_pad : N17 ;
place instance sortie_4<1>_pad : P17 ;
place instance sortie_4<2>_pad : R17 ;
place instance sortie_4<3>_pad : T17 ;
place instance sortie_4<4>_pad : E15 ;
place instance sortie_4<5>_pad : F15 ;
place instance sortie_4<6>_pad : G15 ;
place instance sortie_4<7>_pad : H15 ;
place instance sortie_4<8>_pad : L15 ;
place instance sortie_4<9>_pad : M15 ;
place instance sortie_4<10>_pad : N15 ;
place instance sortie_4<11>_pad : P15 ;

Routing Summary
---------------
Number of unrouted connections : 0
CPU time taken for Routing : 1 hrs 11 mins 37 secs
Split Nets:
The list below identifies those signals which were routed through CLBs
or other blocks. In XDE and XDelay reports, these signals will have
two or more segments. An underscore (_) and a number will be added to
the end of the original signal name to identify the different
segments. To analyze all segments of a signal in XDelay or QueryNet
reports, append the original name with "_*" when prompted for a signal
name.
PPR may route signals through CLBs or other blocks in any of the
following situations:
* The delay on a signal might be reduced by routing it through a CLB,
given the extra flexibility in routing resources and the reduced
capacitive loading on the signal. PPR takes this into consideration.
* The delay on a signal might be reduced by sourcing it from two block
outputs instead of one, which is possible in some block
configurations. PPR will do this where possible.
* A signal on a global buffer may not be able to connect directly to a
load pin, given the placement of that load pin and the other global
resources which are used. PPR will pass the signal through another CLB
and route the load pin using general-purpose interconnect.
* In an XC4000 design, A BUFGP can be sourced only from an IOB. If the
design indicates that a BUFGP is driven from an internal source, PPR
will route the signal through the output path of the IOB in order to
access the BUFGP input.

Segments Original Signal Name
2 imult7_e2_1<7>
3 imult7_e2_1<3>
2 imult7_e2_1<1>
3 i2_mult_7_mult_s1<0>
2 i2_mult_7_mult_s1<2>
2 i2_mult_7/smult_booth_rip1/u739_O
2 i2_mult_7_mult_s1<3>
3 i2_mult_7/smult_booth_rip1/u719_O
2 i2_mult_7/smult_booth_rip1/u704_O

Split Nets:
2 i2_mult_7/smult_booth_rip1/u702_O
2 i2_mult_7/smult_booth_rip1/u676_O
2 i2_mult_7/smult_booth_rip1/u630_O
2 i2_mult_7/smult_booth_rip1/u618_O
2 i2_mult_7/smult_booth_rip1/u589_O
2 imult7_e2_2<7>
2 i2_mult_7/smult_booth_rip1/u468_O
3 imult7_e2_2<5>
4 imult7_e2_2<4>
2 imult7_e2_2<3>
2 imult7_e2_2<2>
2 i2_mult_7/smult_booth_rip1/u92_O
2 i2_mult_7/smult_booth_rip1/u230_O
2 imult7_e1_1<5>
2 imult7_e1_1<7>
2 imult7_e1_1<3>
2 imult7_e1_1<1>
2 i1_mult_7_mult_s1<1>
3 i1_mult_7/smult_booth_rip1/u743_O
3 i1_mult_7/smult_booth_rip1/u737_O
2 i1_mult_7/smult_booth_rip1/u717_O
2 i1_mult_7/smult_booth_rip1/u709_O
2 i1_mult_7/smult_booth_rip1/u699_O
2 i1_mult_7/smult_booth_rip1/u580_O
2 i1_mult_7/smult_booth_rip1/u526_O
2 imult7_e1_2<7>
2 i1_mult_7/smult_booth_rip1/u123_O
3 imult7_e1_2<6>
2 i1_mult_7/smult_booth_rip1/u533_O

Split Nets:
2 i1_mult_7/smult_booth_rip1/u40_O
2 imult7_e1_2<4>
3 i1_mult_7/smult_booth_rip1/u318_O
2 imult7_e1_2<3>
2 imult7_e1_2<2>
2 i1_mult_7/smult_booth_rip1/u9_O
4 imult7_e1_2<1>
2 imult7_e1_2<0>
2 imult7_e1_1<0>
3 i1_sub_8_sub_s1<4>
2 i1_sub_8/sub_rip1/u95_O
2 i1_e_lms_final_sub8_e1_2<9>
3 i1_e_lms_final_sub8_e1_2<4>
2 i1_add_6_add_s1<1>
3 i1_add_6/add_rip1/u9_O
2 i1_add_6/add_rip1/u35_O
2 i1_add_6/add_rip1/u56_O
2 i1_add_6/add_rip1/u51_O
3 i1_add_6/add_rip1/u72_O
2 i1_add_6/add_rip1/u99_O
2 i1_add_6/add_rip1/u96_O
3 i1_add_6/add_rip1/u91_O
3 iadd6_e1_1<10>
2 iadd6_e1_2<10>
3 iadd6_e1_1<9>
3 iadd6_e1_2<9>
2 iadd6_e1_1<8>
3 iadd6_e1_1<5>

Split Nets:
3 iadd6_e1_2<5>
2 iadd6_e1_2<3>
3 iadd6_e1_1<1>
3 imult4_e1_1<9>
3 imult4_e1_1<11>
2 imult4_e1_1<7>
3 imult4_e1_1<5>
2 i1_mult_4_mult_s1<1>
2 i1_mult_4/smult_booth_rip1/u1716_O
2 i1_mult_4/smult_booth_rip1/u1686_O
3 i1_mult_4/smult_booth_rip1/u1671_O
2 i1_mult_4/smult_booth_rip1/u1651_O
2 i1_mult_4/smult_booth_rip1/u1581_O
2 i1_mult_4/smult_booth_rip1/u1171_O
2 i1_mult_4/smult_booth_rip1/u1293_O
2 i1_mult_4/smult_booth_rip1/u1494_O
2 i1_mult_4/smult_booth_rip1/u1185_O
2 i1_mult_4/smult_booth_rip1/u1400_O
2 i1_mult_4/smult_booth_rip1/u1302_O
2 i1_mult_4/smult_booth_rip1/u1240_O
2 i1_mult_4/smult_booth_rip1/u1290_O
3 imult4_e1_2<11>
2 i1_mult_4/smult_booth_rip1/u1367_O
2 imult4_e1_2<10>
2 i1_mult_4/smult_booth_rip1/u264_O
3 imult4_e1_2<9>
2 i1_mult_4/smult_booth_rip1/u1081_O
2 i1_mult_4/smult_booth_rip1/u1078_O
2 i1_mult_4/smult_booth_rip1/u92_O

Split Nets:
2 i1_mult_4/smult_booth_rip1/u1122_O
2 imult4_e1_2<7>
3 i1_mult_4/smult_booth_rip1/u652_O
2 i1_mult_4/smult_booth_rip1/u909_O
2 i1_mult_4/smult_booth_rip1/u823_O
2 imult4_e1_2<6>
3 imult4_e1_2<5>
2 i1_mult_4/smult_booth_rip1/u935_O
2 imult4_e1_2<4>
2 imult4_e1_2<3>
2 i1_mult_4/smult_booth_rip1/u615_O
3 imult4_e1_2<2>
2 i1_mult_4/smult_booth_rip1/u669_O
2 i1_mult_4/smult_booth_rip1/u545_O
2 i1_mult_4/smult_booth_rip1/u348_O
2 i1_mult_4/smult_booth_rip1/u341_O
2 i1_mult_4/smult_booth_rip1/u339_O
2 i1_mult_4/smult_booth_rip1/u12_O
2 imult4_e1_2<1>
2 i1_mult_4/smult_booth_rip1/u412_O
2 i1_mult_4/smult_booth_rip1/u226_O
2 i1_sub_3_sub_s1<1>
3 i1_sub_3/sub_rip1/u24_O
2 i1_sub_3/sub_rip1/u19_O
2 i1_sub_3_sub_s1<5>
3 i1_sub_3_sub_s1<6>
2 i1_sub_3/sub_rip1/u43_O
3 isub3_e1_2<0>

Split Nets:
2 isub3_e1_2<10>
2 isub3_e1_2<9>
2 isub3_e1_2<7>
3 isub3_e1_2<6>
2 isub3_e1_2<5>
2 isub3_e1_2<4>
11 PAD_clk
8 i1_e_lms_final/add6_e1_1_en
6 i1_e_lms_final/sub3_e1_1_en
3 PAD_entree_7<7>
2 PAD_entree_7<6>
3 PAD_entree_7<5>
4 i1_e_lms_final/sortie_4_en
12 PAD_reset<0>
2 i1_e_lms_final/dly5_s<10>
2 i1_e_lms_final/dly5_s<8>
2 i1_e_lms_final/dly5_s<7>
2 i1_e_lms_final/dly5_s<6>
2 i1_e_lms_final/dly5_s<3>
2 i1_e_lms_final/dly5_s<0>
2 i1_e_lms_final/dly7_s<9>
2 i1_e_lms_final/dly7_s<8>
2 i1_e_lms_final/dly7_s<7>
2 i1_e_lms_final/dly7_s<6>
2 i1_e_lms_final/dly7_s<5>
2 i1_e_lms_final/dly7_s<2>
2 i1_e_lms_final/dly7_s<1>
4 i1_e_lms_final/dly9_s<11>
3 i1_e_lms_final/dly9_s<10>
Split Nets:
3 i1_e_lms_final/dly9_s<9>
2 i1_e_lms_final/dly9_s<8>
3 i1_e_lms_final/dly9_s<7>
5 i1_e_lms_final/dly9_s<6>
3 i1_e_lms_final/dly9_s<5>
2 i1_e_lms_final/dly9_s<3>
2 i1_e_lms_final/dly11_s<11>
3 i1_e_lms_final/dly11_s<9>
2 i1_e_lms_final/dly11_s<1>
24 i1_e_lms_final/dly7_s_en
2 i1_e_lms_final/dly51_s<8>
3 i1_e_lms_final/dly51_s<7>
2 i1_e_lms_final/dly51_s<5>
2 i1_e_lms_final/dly51_s<4>
3 i1_e_lms_final/dly51_s<3>
2 i1_e_lms_final/dly51_s<2>
3 i1_e_lms_final/dly51_s<1>
17 i1_e_lms_final/dly5_s_en
2 i1_e_lms_final/dly50_s<9>
2 i1_e_lms_final/dly50_s<7>
2 i1_e_lms_final/dly49_s<2>
15 i1_e_lms_final/c_step_n<2>
2 i1_e_lms_final/dly47_s<11>
3 i1_e_lms_final/dly47_s<0>
5 i1_e_lms_final/c_step<2>
2 i1_e_lms_final/dly46_s<5>
2 i1_e_lms_final/dly45_s<11>
2 i1_e_lms_final/dly45_s<9>

Split Nets:
2 i1_e_lms_final/dly45_s<6>
2 i1_e_lms_final/dly43_s<11>
2 i1_e_lms_final/dly43_s<3>
2 i1_e_lms_final/dly41_s<11>
2 i1_e_lms_final/dly41_s<8>
2 i1_e_lms_final/dly41_s<5>
2 i1_e_lms_final/dly41_s<4>
2 i1_e_lms_final/dly39_s<9>
2 i1_e_lms_final/dly39_s<8>
2 i1_e_lms_final/dly37_s<11>
2 i1_e_lms_final/dly37_s<5>
2 i1_e_lms_final/dly37_s<4>
3 i1_e_lms_final/dly37_s<2>
2 i1_e_lms_final/dly37_s<1>
2 i1_e_lms_final/dly25_s<6>
2 i1_e_lms_final/dly25_s<1>
2 i1_e_lms_final/dly22_s<9>
2 i1_e_lms_final/dly22_s<6>
2 i1_e_lms_final/dly22_s<1>
2 i1_e_lms_final/dly22_s<0>
2 i1_e_lms_final/dly20_s<8>
3 i1_e_lms_final/dly20_s<6>
2 i1_e_lms_final/dly20_s<4>
2 i1_e_lms_final/dly20_s<3>
3 i1_e_lms_final/dly20_s<2>
3 i1_e_lms_final/dly17_s<8>
2 i1_e_lms_final/dly17_s<3>
2 i1_e_lms_final/dly15_s<9>
2 i1_e_lms_final/dly15_s<7>

Split Nets:
2 i1_e_lms_final/dly15_s<6>
2 i1_e_lms_final/dly15_s<3>
2 i1_e_lms_final/c_step<1>
13 i1_e_lms_final/c_step<0>
3 PAD_entree_2<1>
2 PAD_entree_2<2>
2 PAD_entree_1<4>
2 PAD_entree_2<5>
2 PAD_entree_4<5>
2 PAD_entree_1<7>
4 PAD_entree_5<0>
4 i1_e_lms_final/u324_O
3 PAD_entree_5<1>
2 PAD_entree_6<1>
3 PAD_entree_5<2>
2 PAD_entree_5<4>
2 PAD_entree_6<4>
3 PAD_entree_5<5>
2 PAD_entree_6<6>
13 i1_e_lms_final/u7_O

Information in Other Reports
----------------------------
Since not all pertinent design information is listed in this PPR
report file, this section describes where additional information can
be found.
Information Report File Created By
----------------------------------------- ----------- ----------
Connection of signals between levels of design.mrg XNFMERGE
design hierarchy
Resolution of relative location (RLOC) design.mrg XNFMERGE
constraints through design hierarchy
X-BLOX designs: design rule check for design.prx XNFPREP
pre-expanded design
X-BLOX designs: results of optimization design.blx XBLOX
and module expansion in X-BLOX
Design rule check for invalid and/or design.prp XNFPREP
inefficient use of LCA architecture
Unused or disabled logic removed from design.prp XNFPREP
design, due to sourceless or loadless
signals and VCC or ground connections
XC3000A/L designs: Mapping of design design.crf XNFMAP
logic into each CLB or IOB
XC3000A/L designs: Summary of guided design.crf XNFMAP
partitioning results
========== End of Report ==========