config.help
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r284 | |||
Prompt for target technology | ||||
CONFIG_SYN_INFERRED | ||||
Selects the target technology for memory and pads. | ||||
The following are available: | ||||
- Inferred: Generic FPGA or ASIC targets if your synthesis tool | ||||
is capable of inferring RAMs and pads automatically. | ||||
- Actel ProAsic/P/3 and Axellerator FPGAs | ||||
- Aeroflex UT25CRH Rad-Hard 0.25 um CMOS | ||||
- Altera: Most Altera FPGA families | ||||
- Altera-Stratix: Altera Stratix FPGA family | ||||
- Altera-StratixII: Altera Stratix-II FPGA family | ||||
- ATC18: Atmel-Nantes 0.18 um rad-hard CMOS | ||||
- IHP25: IHP 0.25 um CMOS | ||||
- IHP25RH: IHP Rad-Hard 0.25 um CMOS | ||||
- Lattice : EC/ECP/XP FPGAs | ||||
- Quicklogic : Eclipse/E/II FPGAs | ||||
- UMC-0.18 : UMC 0.18 um CMOS with Virtual Silicon libraries | ||||
- Xilinx-Spartan/2/3: Xilinx Spartan/2/3 libraries | ||||
- Xilinx-Spartan3E: Xilinx Spartan3E libraries | ||||
- Xilinx-Virtex/E: Xilinx Virtex/E libraries | ||||
- Xilinx-Virtex2/4/5: Xilinx Virtex2/4/5 libraries | ||||
Ram library | ||||
CONFIG_MEM_VIRAGE | ||||
Select RAM generators for ASIC targets. | ||||
Infer ram | ||||
CONFIG_SYN_INFER_RAM | ||||
Say Y here if you want the synthesis tool to infer your | ||||
RAM automatically. Say N to directly instantiate technology- | ||||
specific RAM cells for the selected target technology package. | ||||
Infer pads | ||||
CONFIG_SYN_INFER_PADS | ||||
Say Y here if you want the synthesis tool to infer pads. | ||||
Say N to directly instantiate technology-specific pads from | ||||
the selected target technology package. | ||||
No async reset | ||||
CONFIG_SYN_NO_ASYNC | ||||
Say Y here if you disable asynchronous reset in some of the IP cores. | ||||
Might be necessary if the target library does not have cells with | ||||
asynchronous set/reset. | ||||
Scan support | ||||
CONFIG_SYN_SCAN | ||||
Say Y here to enable scan support in some cores. This will enable | ||||
the scan support generics where available and add logic to make | ||||
the design testable using full-scan. | ||||
Use Virtex CLKDLL for clock synchronisation | ||||
CONFIG_CLK_INFERRED | ||||
Certain target technologies include clock generators to scale or | ||||
phase-adjust the system and SDRAM clocks. This is currently supported | ||||
for Xilinx, Altera and Proasic3 FPGAs. Depending on technology, you | ||||
can select to use the Xilinx CKLDLL macro (Virtex, VirtexE, Spartan1/2), | ||||
the Xilinx DCM (Virtex-2, Spartan3, Virtex-4), the Altera ALTDLL | ||||
(Stratix, Cyclone), or the Proasic3 PLL. Choose the 'inferred' | ||||
option to skip a clock generator. | ||||
Clock multiplier | ||||
CONFIG_CLK_MUL | ||||
When using the Xilinx DCM or Altera ALTPLL, the system clock can | ||||
be multiplied with a factor of 2 - 32, and divided by a factor of | ||||
1 - 32. This makes it possible to generate almost any desired | ||||
processor frequency. When using the Xilinx CLKDLL generator, | ||||
the resulting frequency scale factor (mul/div) must be one of | ||||
1/2, 1 or 2. On Proasic3, the factor can be 1 - 128. | ||||
WARNING: The resulting clock must be within the limits specified | ||||
by the target FPGA family. | ||||
Clock divider | ||||
CONFIG_CLK_DIV | ||||
When using the Xilinx DCM or Altera ALTPLL, the system clock can | ||||
be multiplied with a factor of 2 - 32, and divided by a factor of | ||||
1 - 32. This makes it possible to generate almost any desired | ||||
processor frequency. When using the Xilinx CLKDLL generator, | ||||
the resulting frequency scale factor (mul/div) must be one of | ||||
1/2, 1 or 2. On Proasic3, the factor can be 1 - 128. | ||||
WARNING: The resulting clock must be within the limits specified | ||||
by the target FPGA family. | ||||
Output clock divider | ||||
CONFIG_OCLK_DIV | ||||
When using the Proasic3 PLL, the system clock is generated by three | ||||
parameters: input clock multiplication, input clock division and | ||||
output clock division. Only certain values of these parameters | ||||
are allowed, but unfortunately this is not documented by Actel. | ||||
To find the correct values, run the Libero Smartgen tool and | ||||
insert you desired input and output clock frequencies in the | ||||
Static PLL configurator. The mul/div factors can then be read | ||||
out from tool. | ||||
System clock multiplier | ||||
CONFIG_CLKDLL_1_2 | ||||
The Xilinx CLKDLL can scale the input clock with a factor of 0.5, 1.0, | ||||
or 2.0. Useful when the target board has an oscillator with a too high | ||||
(or low) frequency for your design. The divided clock will be used as the | ||||
main clock for the whole processor (except PCI and ethernet clocks). | ||||
System clock multiplier | ||||
CONFIG_DCM_2_3 | ||||
The Xilinx DCM and Altera ALTDLL can scale the input clock with a large | ||||
range of factors. Useful when the target board has an oscillator with a | ||||
too high (or low) frequency for your design. The divided clock will | ||||
be used as the main clock for the whole processor (except PCI and | ||||
ethernet clocks). NOTE: the resulting frequency must be at least | ||||
24 MHz or the DCM and ALTDLL might not work. | ||||
Enable CLKDLL for PCI clock | ||||
CONFIG_PCI_CLKDLL | ||||
Say Y here to re-synchronize the PCI clock using a | ||||
Virtex BUFGDLL macro. Will improve PCI clock-to-output | ||||
delays on the expense of input-setup requirements. | ||||
Use PCI clock system clock | ||||
CONFIG_PCI_SYSCLK | ||||
Say Y here to the PCI clock to generate the system clock. | ||||
The PCI clock can be scaled using the DCM or CLKDLL to | ||||
generate a suitable processor clock. | ||||
External SDRAM clock feedback | ||||
CONFIG_CLK_NOFB | ||||
Say Y here to disable the external clock feedback to synchronize the | ||||
SDRAM clock. This option is necessary if your board or design does not | ||||
have an external clock feedback that is connected to the pllref input | ||||
of the clock generator. | ||||
Number of processors | ||||
CONFIG_PROC_NUM | ||||
The number of processor cores. The LEON3MP design can accomodate | ||||
up to 4 LEON3 processor cores. Use 1 unless you know what you are | ||||
doing ... | ||||
Number of SPARC register windows | ||||
CONFIG_IU_NWINDOWS | ||||
The SPARC architecture (and LEON) allows 2 - 32 register windows. | ||||
However, any number except 8 will require that you modify and | ||||
recompile your run-time system or kernel. Unless you know what | ||||
you are doing, use 8. | ||||
SPARC V8 multiply and divide instruction | ||||
CONFIG_IU_V8MULDIV | ||||
If you say Y here, the SPARC V8 multiply and divide instructions | ||||
will be implemented. The instructions are: UMUL, UMULCC, SMUL, | ||||
SMULCC, UDIV, UDIVCC, SDIV, SDIVCC. In code containing frequent | ||||
integer multiplications and divisions, significant performance | ||||
increase can be achieved. Emulated floating-point operations will | ||||
also benefit from this option. | ||||
By default, the gcc compiler does not emit multiply or divide | ||||
instructions and your code must be compiled with -mv8 to see any | ||||
performance increase. On the other hand, code compiled with -mv8 | ||||
will generate an illegal instruction trap when executed on processors | ||||
with this option disabled. | ||||
The divider consumes approximately 2 kgates, the multiplier 6 kgates. | ||||
Multiplier latency | ||||
CONFIG_IU_MUL_LATENCY_2 | ||||
Implementation options for the integer multiplier. | ||||
Type Implementation issue-rate/latency | ||||
2-clocks 32x32 pipelined multiplier 1/2 | ||||
4-clocks 16x16 standard multiplier 4/4 | ||||
5-clocks 16x16 pipelined multiplier 4/5 | ||||
Multiplier latency | ||||
CONFIG_IU_MUL_MAC | ||||
If you say Y here, the SPARC V8e UMAC/SMAC (multiply-accumulate) | ||||
instructions will be enabled. The instructions implement a | ||||
single-cycle 16x16->32 bits multiply with a 40-bits accumulator. | ||||
The details of these instructions can be found in the LEON manual, | ||||
This option is only available when 16x16 multiplier is used. | ||||
Single vector trapping | ||||
CONFIG_IU_SVT | ||||
Single-vector trapping is a SPARC V8e option to reduce code-size | ||||
in small applications. If enabled, the processor will jump to | ||||
the address of trap 0 (tt = 0x00) for all traps. No trap table | ||||
is then needed. The trap type is present in %psr.tt and must | ||||
be decoded by the O/S. Saves 4 Kbyte of code, but increases | ||||
trap and interrupt overhead. Currently, the only O/S supporting | ||||
this option is eCos. To enable SVT, the O/S must also set bit 13 | ||||
in %asr17. | ||||
Load latency | ||||
CONFIG_IU_LDELAY | ||||
Defines the pipeline load delay (= pipeline cycles before the data | ||||
from a load instruction is available for the next instruction). | ||||
One cycle gives best performance, but might create a critical path | ||||
on targets with slow (data) cache memories. A 2-cycle delay can | ||||
improve timing but will reduce performance with about 5%. | ||||
Reset address | ||||
CONFIG_IU_RSTADDR | ||||
By default, a SPARC processor starts execution at address 0. | ||||
With this option, any 4-kbyte aligned reset start address can be | ||||
choosen. Keep at 0 unless you really know what you are doing. | ||||
Power-down | ||||
CONFIG_PWD | ||||
Say Y here to enable the power-down feature of the processor. | ||||
Might reduce the maximum frequency slightly on FPGA targets. | ||||
For details on the power-down operation, see the LEON3 manual. | ||||
Hardware watchpoints | ||||
CONFIG_IU_WATCHPOINTS | ||||
The processor can have up to 4 hardware watchpoints, allowing to | ||||
create both data and instruction breakpoints at any memory location, | ||||
also in PROM. Each watchpoint will use approximately 500 gates. | ||||
Use 0 to disable the watchpoint function. | ||||
Floating-point enable | ||||
CONFIG_FPU_ENABLE | ||||
Say Y here to enable the floating-point interface for the MEIKO | ||||
or GRFPU. Note that no FPU's are provided with the GPL version | ||||
of GRLIB. Both the Gaisler GRFPU and the Meiko FPU are commercial | ||||
cores and must be obtained separately. | ||||
FPU selection | ||||
CONFIG_FPU_GRFPU | ||||
Select between Gaisler Research's GRFPU and GRFPU-lite FPUs or the Sun | ||||
Meiko FPU core. All cores are fully IEEE-754 compatible and support | ||||
all SPARC FPU instructions. | ||||
GRFPU Multiplier | ||||
CONFIG_FPU_GRFPU_INFMUL | ||||
On FPGA targets choose inferred multiplier. For ASIC implementations | ||||
choose between Synopsys Design Ware (DW) multiplier or Module | ||||
Generator (ModGen) multiplier. The DW multiplier gives better results | ||||
(smaller area and better timing) but requires a DW license. | ||||
The ModGen multiplier is part of GRLIB and does not require a license. | ||||
Shared GRFPU | ||||
CONFIG_FPU_GRFPU_SH | ||||
If enabled multiple CPU cores will share one GRFPU. | ||||
GRFPC Configuration | ||||
CONFIG_FPU_GRFPC0 | ||||
Configures the GRFPU-LITE controller. | ||||
In simple configuration controller executes FP instructions | ||||
in parallel with integer instructions. FP operands are fetched | ||||
in the register file stage and the result is written in the write | ||||
stage. This option uses least area resources. | ||||
Data forwarding configuration gives ~ 10 % higher FP performance than | ||||
the simple configuration by adding data forwarding between the pipeline | ||||
stages. | ||||
Non-blocking controller allows FP load and store instructions to | ||||
execute in parallel with FP instructions. The performance increase is | ||||
~ 20 % for FP applications. This option uses most logic resources and | ||||
is suitable for ASIC implementations. | ||||
Floating-point netlist | ||||
CONFIG_FPU_NETLIST | ||||
Say Y here to use a VHDL netlist of the GRFPU-Lite. This is | ||||
only available in certain versions of grlib. | ||||
Enable Instruction cache | ||||
CONFIG_ICACHE_ENABLE | ||||
The instruction cache should always be enabled to allow | ||||
maximum performance. Some low-end system might want to | ||||
save area and disable the cache, but this will reduce | ||||
the performance with a factor of 2 - 3. | ||||
Enable Data cache | ||||
CONFIG_DCACHE_ENABLE | ||||
The data cache should always be enabled to allow | ||||
maximum performance. Some low-end system might want to | ||||
save area and disable the cache, but this will reduce | ||||
the performance with a factor of 2 at least. | ||||
Instruction cache associativity | ||||
CONFIG_ICACHE_ASSO1 | ||||
The instruction cache can be implemented as a multi-set cache with | ||||
1 - 4 sets. Higher associativity usually increases the cache hit | ||||
rate and thereby the performance. The downside is higher power | ||||
consumption and increased gate-count for tag comparators. | ||||
Note that a 1-set cache is effectively a direct-mapped cache. | ||||
Instruction cache set size | ||||
CONFIG_ICACHE_SZ1 | ||||
The size of each set in the instuction cache (kbytes). Valid values | ||||
are 1 - 64 in binary steps. Note that the full range is only supported | ||||
by the generic and virtex2 targets. Most target packages are limited | ||||
to 2 - 16 kbyte. Large set size gives higher performance but might | ||||
affect the maximum frequency (on ASIC targets). The total instruction | ||||
cache size is the number of set multiplied with the set size. | ||||
Instruction cache line size | ||||
CONFIG_ICACHE_LZ16 | ||||
The instruction cache line size. Can be set to either 16 or 32 | ||||
bytes per line. Instruction caches typically benefit from larger | ||||
line sizes, but on small caches it migh be better with 16 bytes/line | ||||
to limit eviction miss rate. | ||||
Instruction cache replacement algorithm | ||||
CONFIG_ICACHE_ALGORND | ||||
Cache replacement algorithm for caches with 2 - 4 sets. The 'random' | ||||
algorithm selects the set to evict randomly. The least-recently-replaced | ||||
(LRR) algorithm evicts the set least recently replaced. The least- | ||||
recently-used (LRU) algorithm evicts the set least recently accessed. | ||||
The random algorithm uses a simple 1- or 2-bit counter to select | ||||
the eviction set and has low area overhead. The LRR scheme uses one | ||||
extra bit in the tag ram and has therefore also low area overhead. | ||||
However, the LRR scheme can only be used with 2-set caches. The LRU | ||||
scheme has typically the best performance but also highest area overhead. | ||||
A 2-set LRU uses 1 flip-flop per line, a 3-set LRU uses 3 flip-flops | ||||
per line, and a 4-set LRU uses 5 flip-flops per line to store the access | ||||
history. | ||||
Instruction cache locking | ||||
CONFIG_ICACHE_LOCK | ||||
Say Y here to enable cache locking in the instruction cache. | ||||
Locking can be done on cache-line level, but will increase the | ||||
width of the tag ram with one bit. If you don't know what | ||||
locking is good for, it is safe to say N. | ||||
Data cache associativity | ||||
CONFIG_DCACHE_ASSO1 | ||||
The data cache can be implemented as a multi-set cache with | ||||
1 - 4 sets. Higher associativity usually increases the cache hit | ||||
rate and thereby the performance. The downside is higher power | ||||
consumption and increased gate-count for tag comparators. | ||||
Note that a 1-set cache is effectively a direct-mapped cache. | ||||
Data cache set size | ||||
CONFIG_DCACHE_SZ1 | ||||
The size of each set in the data cache (kbytes). Valid values are | ||||
1 - 64 in binary steps. Note that the full range is only supported | ||||
by the generic and virtex2 targets. Most target packages are limited | ||||
to 2 - 16 kbyte. A large cache gives higher performance but the | ||||
data cache is timing critical an a too large setting might affect | ||||
the maximum frequency (on ASIC targets). The total data cache size | ||||
is the number of set multiplied with the set size. | ||||
Data cache line size | ||||
CONFIG_DCACHE_LZ16 | ||||
The data cache line size. Can be set to either 16 or 32 bytes per | ||||
line. A smaller line size gives better associativity and higher | ||||
cache hit rate, but requires a larger tag memory. | ||||
Data cache replacement algorithm | ||||
CONFIG_DCACHE_ALGORND | ||||
See the explanation for instruction cache replacement algorithm. | ||||
Data cache locking | ||||
CONFIG_DCACHE_LOCK | ||||
Say Y here to enable cache locking in the data cache. | ||||
Locking can be done on cache-line level, but will increase the | ||||
width of the tag ram with one bit. If you don't know what | ||||
locking is good for, it is safe to say N. | ||||
Data cache snooping | ||||
CONFIG_DCACHE_SNOOP | ||||
Say Y here to enable data cache snooping on the AHB bus. Is only | ||||
useful if you have additional AHB masters such as the DSU or a | ||||
target PCI interface. Note that the target technology must support | ||||
dual-port RAMs for this option to be enabled. Dual-port RAMS are | ||||
currently supported on Virtex/2, Virage and Actel targets. | ||||
Data cache snooping implementation | ||||
CONFIG_DCACHE_SNOOP_FAST | ||||
The default snooping implementation is 'slow', which works if you | ||||
don't have AHB slaves in cacheable areas capable of zero-waitstates | ||||
non-sequential write accesses. Otherwise use 'fast' and suffer a | ||||
few kgates extra area. This option is currently only needed in | ||||
multi-master systems with the SSRAM or DDR memory controllers. | ||||
Separate snoop tags | ||||
CONFIG_DCACHE_SNOOP_SEPTAG | ||||
Enable a separate memory to store the data tags used for snooping. | ||||
This is necessary when snooping support is wanted in systems | ||||
with MMU, typically for SMP systems. In this case, the snoop | ||||
tags will contain the physical tag address while the normal | ||||
tags contain the virtual tag address. This option can also be | ||||
together with the 'fast snooping' option to enable snooping | ||||
support on technologies without dual-port RAMs. In such case, | ||||
the snoop tag RAM will be implemented using a two-port RAM. | ||||
Fixed cacheability map | ||||
CONFIG_CACHE_FIXED | ||||
If this variable is 0, the cacheable memory regions are defined | ||||
by the AHB plug&play information (default). To overriden the | ||||
plug&play settings, this variable can be set to indicate which | ||||
areas should be cached. The value is treated as a 16-bit hex value | ||||
with each bit defining if a 256 Mbyte segment should be cached or not. | ||||
The right-most (LSB) bit defines the cacheability of AHB address | ||||
0 - 256 MByte, while the left-most bit (MSB) defines AHB address | ||||
3840 - 4096 MByte. If the bit is set, the corresponding area is | ||||
cacheable. A value of 00F3 defines address 0 - 0x20000000 and | ||||
0x40000000 - 0x80000000 as cacheable. | ||||
Local data ram | ||||
CONFIG_DCACHE_LRAM | ||||
Say Y here to add a local ram to the data cache controller. | ||||
Accesses to the ram (load/store) will be performed at 0 waitstates | ||||
and store data will never be written back to the AHB bus. | ||||
Size of local data ram | ||||
CONFIG_DCACHE_LRAM_SZ1 | ||||
Defines the size of the local data ram in Kbytes. Note that most | ||||
technology libraries do not support larger rams than 16 Kbyte. | ||||
Start address of local data ram | ||||
CONFIG_DCACHE_LRSTART | ||||
Defines the 8 MSB bits of start address of the local data ram. | ||||
By default set to 8f (start address = 0x8f000000), but any value | ||||
(except 0) is possible. Note that the local data ram 'shadows' | ||||
a 16 Mbyte block of the address space. | ||||
MMU enable | ||||
CONFIG_MMU_ENABLE | ||||
Say Y here to enable the Memory Management Unit. | ||||
MMU split icache/dcache table lookaside buffer | ||||
CONFIG_MMU_COMBINED | ||||
Select "combined" for a combined icache/dcache table lookaside buffer, | ||||
"split" for a split icache/dcache table lookaside buffer | ||||
MMU tlb replacement scheme | ||||
CONFIG_MMU_REPARRAY | ||||
Select "LRU" to use the "least recently used" algorithm for TLB | ||||
replacement, or "Increment" for a simple incremental replacement | ||||
scheme. | ||||
Combined i/dcache tlb | ||||
CONFIG_MMU_I2 | ||||
Select the number of entries for the instruction TLB, or the | ||||
combined icache/dcache TLB if such is used. | ||||
Split tlb, dcache | ||||
CONFIG_MMU_D2 | ||||
Select the number of entries for the dcache TLB. | ||||
Fast writebuffer | ||||
CONFIG_MMU_FASTWB | ||||
Only selectable if split tlb is enabled. In case fast writebuffer is | ||||
enabled the tlb hit will be made concurrent to the cache hit. This | ||||
leads to higher store performance, but increased power and area. | ||||
MMU pagesize | ||||
CONFIG_MMU_PAGE_4K | ||||
The deafult SPARC V8 SRMMU page size is 4 Kbyte. This limits the | ||||
cache way size to 4 Kbyte, and total data cache size to 16 Kbyte, | ||||
when the MMU is used. To increase the maximum data cache size, | ||||
the MMU pages size can be increased to up 32 Kbyte. This will | ||||
give a maximum data cache size of 128 Kbyte. | ||||
Note that an MMU page size different than 4 Kbyte will require | ||||
a special linux tool-chain if glibc is used. If you don't know | ||||
what you are doing, stay with 4 Kbyte ... | ||||
DSU enable | ||||
CONFIG_DSU_ENABLE | ||||
The debug support unit (DSU) allows non-intrusive debugging and tracing | ||||
of both executed instructions and AHB transfers. If you want to enable | ||||
the DSU, say Y here and select the configuration below. | ||||
Trace buffer enable | ||||
CONFIG_DSU_TRACEBUF | ||||
Say Y to enable the trace buffer. The buffer is not necessary for | ||||
debugging, only for tracing instructions and data transfers. | ||||
Enable instruction tracing | ||||
CONFIG_DSU_ITRACE | ||||
If you say Y here, an instruction trace buffer will be implemented | ||||
in each processor. The trace buffer will trace executed instructions | ||||
and their results, and place them in a circular buffer. The buffer | ||||
can be read out by any AHB master, and in particular by the debug | ||||
communication link. | ||||
Size of trace buffer | ||||
CONFIG_DSU_ITRACESZ1 | ||||
Select the buffer size (in kbytes) for the instruction trace buffer. | ||||
Each line in the buffer needs 16 bytes. A 128-entry buffer will thus | ||||
need 2 kbyte. | ||||
Enable AHB tracing | ||||
CONFIG_DSU_ATRACE | ||||
If you say Y here, an AHB trace buffer will be implemented in the | ||||
debug support unit processor. The AHB buffer will trace all transfers | ||||
on the AHB bus and save them in a circular buffer. The trace buffer | ||||
can be read out by any AHB master, and in particular by the debug | ||||
communication link. | ||||
Size of trace buffer | ||||
CONFIG_DSU_ATRACESZ1 | ||||
Select the buffer size (in kbytes) for the AHB trace buffer. | ||||
Each line in the buffer needs 16 bytes. A 128-entry buffer will thus | ||||
need 2 kbyte. | ||||
LEON3FT enable | ||||
CONFIG_LEON3FT_EN | ||||
Say Y here to use the fault-tolerant LEON3FT core instead of the | ||||
standard non-FT LEON3. | ||||
IU Register file protection | ||||
CONFIG_IUFT_NONE | ||||
Select the FT implementation in the LEON3FT integer unit | ||||
register file. The options include parity, parity with | ||||
sparing, 7-bit BCH and TMR. | ||||
FPU Register file protection | ||||
CONFIG_FPUFT_EN | ||||
Say Y to enable SEU protection of the FPU register file. | ||||
The GRFPU will be protected using 8-bit parity without restart, while | ||||
the GRFPU-Lite will be protected with 4-bit parity with restart. If | ||||
disabled the FPU register file will be implemented using flip-flops. | ||||
Cache memory error injection | ||||
CONFIG_RF_ERRINJ | ||||
Say Y here to enable error injection in to the IU/FPU regfiles. | ||||
Affects only simulation. | ||||
Cache memory protection | ||||
CONFIG_CACHE_FT_EN | ||||
Enable SEU error-correction in the cache memories. | ||||
Cache memory error injection | ||||
CONFIG_CACHE_ERRINJ | ||||
Say Y here to enable error injection in to the cache memories. | ||||
Affects only simulation. | ||||
Leon3ft netlist | ||||
CONFIG_LEON3_NETLIST | ||||
Say Y here to use a VHDL netlist of the LEON3FT. This is | ||||
only available in certain versions of grlib. | ||||
IU assembly printing | ||||
CONFIG_IU_DISAS | ||||
Enable printing of executed instructions to the console. | ||||
IU assembly printing in netlist | ||||
CONFIG_IU_DISAS_NET | ||||
Enable printing of executed instructions to the console also | ||||
when simulating a netlist. NOTE: with this option enabled, it | ||||
will not be possible to pass place&route. | ||||
32-bit program counters | ||||
CONFIG_DEBUG_PC32 | ||||
Since the LSB 2 bits of the program counters always are zero, they are | ||||
normally not implemented. If you say Y here, the program counters will | ||||
be implemented with full 32 bits, making debugging of the VHDL model | ||||
much easier. Turn of this option for synthesis or you will be wasting | ||||
area. | ||||
CONFIG_AHB_DEFMST | ||||
Sets the default AHB master (see AMBA 2.0 specification for definition). | ||||
Should not be set to a value larger than the number of AHB masters - 1. | ||||
For highest processor performance, leave it at 0. | ||||
Default AHB master | ||||
CONFIG_AHB_RROBIN | ||||
Say Y here to enable round-robin arbitration of the AHB bus. A N will | ||||
select fixed priority, with the master with the highest bus index having | ||||
the highest priority. | ||||
Support AHB split-transactions | ||||
CONFIG_AHB_SPLIT | ||||
Say Y here to enable AHB split-transaction support in the AHB arbiter. | ||||
Unless you actually have an AHB slave that can generate AHB split | ||||
responses, say N and save some gates. | ||||
Default AHB master | ||||
CONFIG_AHB_IOADDR | ||||
Selects the MSB adddress (HADDR[31:20]) of the AHB IO area, as defined | ||||
in the plug&play extentions of the AMBA bus. Should be kept to FFF | ||||
unless you really know what you are doing. | ||||
APB bridge address | ||||
CONFIG_APB_HADDR | ||||
Selects the MSB adddress (HADDR[31:20]) of the APB bridge. Should be | ||||
kept at 800 for software compatibility. | ||||
AHB monitor | ||||
CONFIG_AHB_MON | ||||
Say Y to enable the AHB bus monitor. The monitor will check for | ||||
illegal AHB transactions during simulation. It has no impact on | ||||
synthesis. | ||||
Report AHB errors | ||||
CONFIG_AHB_MONERR | ||||
Print out detected AHB violations on console. | ||||
Report AHB warnings | ||||
CONFIG_AHB_MONWAR | ||||
Print out detected AHB warnings on console. | ||||
DSU enable | ||||
CONFIG_DSU_UART | ||||
Say Y to enable the AHB uart (serial-to-AHB). This is the most | ||||
commonly used debug communication link. | ||||
JTAG Enable | ||||
CONFIG_DSU_JTAG | ||||
Say Y to enable the JTAG debug link (JTAG-to-AHB). Debugging is done | ||||
with GRMON through the boards JTAG chain at speed of 300 kbits/s. | ||||
Supported JTAG cables are Xilinx Parallel Cable III and IV. | ||||
Ethernet DSU enable | ||||
CONFIG_DSU_ETH | ||||
Say Y to enable the Ethernet Debug Communication Link (EDCL). The link | ||||
provides a DSU gateway between ethernet and the AHB bus. Debugging is | ||||
done at 10 or 100 Mbit/s, using the GRMON debug monitor. You must | ||||
enable the GRETH Ethernet MAC for this option to become active. | ||||
Size of EDCL trace buffer | ||||
CONFIG_DSU_ETHSZ1 | ||||
Select the buffer size (in kbytes) for the EDCL. 1 or 2 kbyte is | ||||
usually enough, while a larger buffer will increase the transfer rate. | ||||
When operating at 100 Mbit, use a buffer size of at least 8 kbyte for | ||||
maximum throughput. | ||||
MSB IP address | ||||
CONFIG_DSU_IPMSB | ||||
Set the MSB 16 bits of the IP address of the EDCL. | ||||
LSB IP address | ||||
CONFIG_DSU_IPLSB | ||||
Set the LSB 16 bits of the IP address of the EDCL. | ||||
MSB ethernet address | ||||
CONFIG_DSU_ETHMSB | ||||
Set the MSB 24 bits of the ethernet address of the EDCL. | ||||
LSB ethernet address | ||||
CONFIG_DSU_ETHLSB | ||||
Set the LSB 24 bits of the ethernet address of the EDCL. | ||||
Programmable MAC/IP address | ||||
CONFIG_DSU_ETH_PROG | ||||
Say Y to make the LSB 4 bits of the EDCL MAC and IP address | ||||
configurable using the ethi.edcladdr inputs. | ||||
PROM/SRAM memory controller | ||||
CONFIG_SRCTRL | ||||
Say Y here to enable a simple (and small) PROM/SRAM memory controller. | ||||
The controller has a fixed number of waitstates, and is primarily | ||||
intended for FPGA implementations. The RAM data bus is always 32 bits, | ||||
the PROM can be configured to either 8 or 32 bits (hardwired). | ||||
8-bit memory support | ||||
CONFIG_SRCTRL_8BIT | ||||
If you say Y here, the simple PROM/SRAM memory controller will | ||||
implement 8-bit PROM mode. | ||||
PROM waitstates | ||||
CONFIG_SRCTRL_PROMWS | ||||
Select the number of waitstates for PROM access. | ||||
RAM waitstates | ||||
CONFIG_SRCTRL_RAMWS | ||||
Select the number of waitstates for RAM access. | ||||
IO waitstates | ||||
CONFIG_SRCTRL_IOWS | ||||
Select the number of waitstates for IO access. | ||||
Read-modify-write support | ||||
CONFIG_SRCTRL_RMW | ||||
Say Y here to perform byte- and half-word writes as a | ||||
read-modify-write sequence. This is necessary if your | ||||
SRAM does not have individual byte enables. If you are | ||||
unsure, it is safe to say Y. | ||||
SRAM bank select | ||||
CONFIG_SRCTRL_SRBANKS | ||||
Select number of SRAM banks. | ||||
SRAM bank size select | ||||
CONFIG_SRCTRL_BANKSZ | ||||
Select size of SRAM banks in kBytes. | ||||
PROM address bit select | ||||
CONFIG_SRCTRL_ROMASEL | ||||
Select address bit for PROM bank decoding. | ||||
Leon2 memory controller | ||||
CONFIG_MCTRL_LEON2 | ||||
Say Y here to enable the LEON2 memory controller. The controller | ||||
can access PROM, I/O, SRAM and SDRAM. The bus width for PROM | ||||
and SRAM is programmable to 8-, 16- or 32-bits. | ||||
8-bit memory support | ||||
CONFIG_MCTRL_8BIT | ||||
If you say Y here, the PROM/SRAM memory controller will support | ||||
8-bit mode, i.e. operate from 8-bit devices as if they were 32-bit. | ||||
Say N to save a few hundred gates. | ||||
16-bit memory support | ||||
CONFIG_MCTRL_16BIT | ||||
If you say Y here, the PROM/SRAM memory controller will support | ||||
16-bit mode, i.e. operate from 16-bit devices as if they were 32-bit. | ||||
Say N to save a few hundred gates. | ||||
Write strobe feedback | ||||
CONFIG_MCTRL_WFB | ||||
If you say Y here, the PROM/SRAM write strobes (WRITEN, WEN) will | ||||
be used to enable the data bus drivers during write cycles. This | ||||
will guarantee that the data is still valid on the rising edge of | ||||
the write strobe. If you say N, the write strobes and the data bus | ||||
drivers will be clocked on the rising edge, potentially creating | ||||
a hold time problem in external memory or I/O. However, in all | ||||
practical cases, there is enough capacitance in the data bus lines | ||||
to keep the value stable for a few (many?) nano-seconds after the | ||||
buffers have been disabled, making it safe to say N and remove a | ||||
combinational path in the netlist that might be difficult to | ||||
analyze. | ||||
Write strobe feedback | ||||
CONFIG_MCTRL_5CS | ||||
If you say Y here, the 5th (RAMSN[4]) SRAM chip select signal will | ||||
be enabled. If you don't intend to use it, say N and save some gates. | ||||
SDRAM controller enable | ||||
CONFIG_MCTRL_SDRAM | ||||
Say Y here to enabled the PC100/PC133 SDRAM controller. If you don't | ||||
intend to use SDRAM, say N and save about 1 kgates. | ||||
SDRAM controller inverted clock | ||||
CONFIG_MCTRL_SDRAM_INVCLK | ||||
If you say Y here, the SDRAM controller output signals will be delayed | ||||
with 1/2 clock in respect to the SDRAM clock. This will allow the used | ||||
of an SDRAM clock which in not strictly in phase with the internal | ||||
clock. This option will limit the SDRAM frequency to 40 - 50 MHz. | ||||
On FPGA targets without SDRAM clock synchronizations through PLL/DLL, | ||||
say Y. On ASIC targets, say N and tell your foundry to balance the | ||||
SDRAM clock output. | ||||
SDRAM separate address buses | ||||
CONFIG_MCTRL_SDRAM_SEPBUS | ||||
Say Y here if your SDRAM is connected through separate address | ||||
and data buses (SA & SD). This is the case on the GR-CPCI-XC2V6000 | ||||
board, but not on the GR-PCI-XC2V3000 or Avnet XCV1500E boards. | ||||
64-bit data bus | ||||
CONFIG_MCTRL_SDRAM_BUS64 | ||||
Say Y here to enable 64-bit SDRAM data bus. | ||||
Page burst enable | ||||
CONFIG_MCTRL_PAGE | ||||
Say Y here to enable SDRAM page burst operation. This will implement | ||||
read operations using page bursts rather than 8-word bursts and save | ||||
about 500 gates (100 LUTs). Note that not all SDRAM supports page | ||||
burst, so use this option with care. | ||||
Programmable page burst enable | ||||
CONFIG_MCTRL_PROGPAGE | ||||
Say Y here to enable programmable SDRAM page burst operation. This | ||||
will allow to dynamically enable/disable page burst by setting | ||||
bit 17 in MCFG2. | ||||
SDRAM controller enable | ||||
CONFIG_SDCTRL | ||||
Say Y here to enabled a 32/64-bit PC133 SDRAM controller. | ||||
SDRAM controller inverted clock | ||||
CONFIG_SDCTRL_INVCLK | ||||
If you say Y here, the SDRAM clock will be inverted in respect to the | ||||
system clock and the SDRAM signals. This will limit the SDRAM frequency | ||||
to 50/66 MHz, but has the benefit that you will not need a PLL to | ||||
generate the SDRAM clock. On FPGA targets, say Y. On ASIC targets, | ||||
say N and tell your foundry to balance the SDRAM clock output. | ||||
64-bit data bus | ||||
CONFIG_SDCTRL_BUS64 | ||||
Say Y here to enable 64-bit data bus. | ||||
Page burst enable | ||||
CONFIG_SDCTRL_PAGE | ||||
Say Y here to enable SDRAM page burst operation. This will implement | ||||
read operations using page bursts rather than 8-word bursts and save | ||||
about 500 gates (100 LUTs). Note that not all SDRAM supports page | ||||
burst, so use this option with care. | ||||
Programmable page burst enable | ||||
CONFIG_SDCTRL_PROGPAGE | ||||
Say Y here to enable programmable SDRAM page burst operation. This | ||||
will allow to dynamically enable/disable page burst by setting | ||||
bit 17 in MCFG2. | ||||
On-chip rom | ||||
CONFIG_AHBROM_ENABLE | ||||
Say Y here to add a block on on-chip rom to the AHB bus. The ram | ||||
provides 0-waitstates read access, burst support, and 8-, 16- | ||||
and 32-bit data size. The rom will be syntheised into block rams | ||||
on Xilinx and Altera FPGA devices, and into gates on ASIC | ||||
technologies. GRLIB includes a utility to automatically create | ||||
the rom VHDL model (ahbrom.vhd) from an ELF file. Refer to the GRLIB | ||||
documentation for details. | ||||
On-chip rom address | ||||
CONFIG_AHBROM_START | ||||
Set the start address of AHB ROM (HADDR[31:20]). The ROM will occupy | ||||
a 1 Mbyte slot at the selected address. Default is 000, corresponding | ||||
to AHB address 0x00000000. When address 0x0 is selected, the rom area | ||||
of any other memory controller is set to 0x10000000 to avoid conflicts. | ||||
Enable pipeline register for on-chip rom | ||||
CONFIG_AHBROM_PIPE | ||||
Say Y here to add a data pipeline register to the on-chip rom. | ||||
This should be done when the rom is implemenented in (ASIC) gates, | ||||
or in logic cells on FPGAs. Do not use this option when the rom is | ||||
implemented in block rams. If enabled, the rom will operate with | ||||
one waitstate. | ||||
On-chip ram | ||||
CONFIG_AHBRAM_ENABLE | ||||
Say Y here to add a block on on-chip ram to the AHB bus. The ram | ||||
provides 0-waitstates read access and 0/1 waitstates write access. | ||||
All AHB burst types are supported, as well as 8-, 16- and 32-bit | ||||
data size. | ||||
On-chip ram size | ||||
CONFIG_AHBRAM_SZ1 | ||||
Set the size of the on-chip AHB ram. The ram is infered/instantiated | ||||
as four byte-wide ram slices to allow byte and half-word write | ||||
accesses. It is therefore essential that the target package can | ||||
infer byte-wide rams. This is currently supported on the generic, | ||||
virtex, virtex2, proasic and axellerator targets. | ||||
On-chip ram address | ||||
CONFIG_AHBRAM_START | ||||
Set the start address of AHB RAM (HADDR[31:20]). The RAM will occupy | ||||
a 1 Mbyte slot at the selected address. Default is A00, corresponding | ||||
to AHB address 0xA0000000. | ||||
Gaisler Ethernet MAC enable | ||||
CONFIG_GRETH_ENABLE | ||||
Say Y here to enable the Gaisler Research Ethernet MAC . The MAC has | ||||
one AHB master interface to read and write packets to memory, and one | ||||
APB slave interface for accessing the control registers. | ||||
Gaisler Ethernet 1G MAC enable | ||||
CONFIG_GRETH_GIGA | ||||
Say Y here to enable the Gaisler Research 1000 Mbit Ethernet MAC . | ||||
The 1G MAC is only available in the commercial version of GRLIB, | ||||
so do NOT enable it if you are using the GPL version. | ||||
CONFIG_GRETH_FIFO4 | ||||
Set the depth of the receive and transmit FIFOs in the MAC core. | ||||
The MAC core will perform AHB burst read/writes with half the | ||||
size of the FIFO depth. | ||||
CAN interface enable | ||||
CONFIG_CAN_ENABLE | ||||
Say Y here to enable the CAN interace from OpenCores. The core has one | ||||
AHB slave interface for accessing the control registers. The CAN core | ||||
ir register-compatible with the SAJ1000 core from Philips. | ||||
CAN register address | ||||
CONFIG_CANIO | ||||
The control registers of the CAN core occupy 4 kbyte, and are | ||||
mapped in the AHB bus I/O area (0xFFF00000 - 0xFFFFF000). This setting | ||||
defines at which address in the I/O area the registers appear (HADDR[19:8]). | ||||
CAN interrupt | ||||
CONFIG_CANIRQ | ||||
Defines which interrupt number the CAN core will generate. | ||||
CAN loob-back testing | ||||
CONFIG_CANLOOP | ||||
If you say Y here, the receiver and trasmitter of the CAN core will | ||||
be connected together in a loop-back fashion. This will make it | ||||
possible to perform loop-back test, but not data will be sent | ||||
or received from the outside. ONLY for testing! | ||||
CAN Synchronous reset | ||||
CONFIG_CAN_SYNCRST | ||||
If you say Y here, the CAN core will be implemented with | ||||
synchronous reset rather than asynchronous. This is needed | ||||
when the target library does not implement registers with | ||||
async reset. Unless you know what you are doing, say N. | ||||
CAN FT memories | ||||
CONFIG_CAN_FT | ||||
If you say Y here, the CAN FIFOs will be implemented using | ||||
SEU protected RAM blocks. Only applicable to the FT version | ||||
of grlib. | ||||
PCI interface type | ||||
CONFIG_PCI_SIMPLE_TARGET | ||||
The target-only PCI interface provides a simple target interface | ||||
without fifos. It is small and robust, and is suitable to be used | ||||
for DSU communications via PCI. | ||||
PCI interface type | ||||
CONFIG_PCI_MASTER_TARGET | ||||
The master-target PCI interface provides a high-performance 32-bit | ||||
PCI interface with configurable FIFOs and optional DMA channel. | ||||
PCI interface type | ||||
CONFIG_PCI_MASTER_TARGET_DMA | ||||
Say Y here to enable a DMA controller in the PCI master-target core. | ||||
The DMA controller can perform PCI<->memory data transfers | ||||
independently of the processor. | ||||
PCI vendor id | ||||
CONFIG_PCI_VENDORID | ||||
Sets the PCI vendor ID in the PCI configuration area. | ||||
PCI device id | ||||
CONFIG_PCI_DEVICEID | ||||
Sets the PCI device ID in the PCI configuration area. | ||||
PCI initiator address | ||||
CONFIG_PCI_HADDR | ||||
Sets the MSB AHB adress (HADDR[31:20]) of the PCI initiator area. | ||||
PCI FIFO depth | ||||
CONFIG_PCI_FIFO8 | ||||
The number words in the PCI FIFO buffers in the master-target | ||||
core. The master interface uses four 33-bit wide FIFOs, while the | ||||
target interface uses two. | ||||
PCI arbiter enable | ||||
CONFIG_PCI_ARBITER | ||||
To enable a PCI arbiter, say Y here. | ||||
PCI APB interface enable | ||||
CONFIG_PCI_ARBITER_APB | ||||
Say Y here to enable the APB interface on the PCI arbiter. This makes | ||||
it possible to dynamically re-assign PCI master priorities. See the | ||||
PCI arbiter manual for details. | ||||
PCI arbiter request signals | ||||
CONFIG_PCI_ARBITER_NREQ | ||||
The number of PCI bus request/grant pairs. Should be not | ||||
be more than 8. Note that the processor needs one, so the | ||||
minimum should be 2. | ||||
PCI trace buffer | ||||
CONFIG_PCI_TRACE | ||||
The PCI trace buffer implements a simple on-chip logic analyzer | ||||
to trace the PCI signals. The PCI AD bus and most control signals | ||||
are stored in a circular buffer, and can be read out by the DSU | ||||
or any other AHB master. See the manual for detailed operation. | ||||
Only available for target technologies with dual-port rams. | ||||
PCI trace buffer depth | ||||
CONFIG_PCI_TRACE256 | ||||
Select the number of entries in the PCI trace buffer. Each entry | ||||
will use 6 bytes of on-chip (block) ram. | ||||
Spacewire link | ||||
CONFIG_SPW_ENABLE | ||||
Say Y here to enable one or more Spacewire serial links. The links | ||||
are based on the GRSPW core from Gaisler Research. | ||||
Number of spacewire links | ||||
CONFIG_SPW_NUM | ||||
Select the number of links to implement. Each link will be a | ||||
separate AHB master and APB slave for configuration. | ||||
AHB FIFO depth | ||||
CONFIG_SPW_AHBFIFO4 | ||||
Select the AHB FIFO depth (in 32-bit words). | ||||
RX FIFO depth | ||||
CONFIG_SPW_RXFIFO16 | ||||
Select the receiver FIFO depth (in bytes). | ||||
RMAP protocol | ||||
CONFIG_SPW_RMAP | ||||
Enable hardware target support for the RMAP protocol ( | ||||
draft C for GRSPW1 and ECSS-E-ST-50-11C Draft V1.3 | ||||
for GRSPW2). | ||||
RMAP Buffer depth | ||||
CONFIG_SPW_RMAPBUF2 | ||||
Select the size of the RMAP buffer (in bytes). | ||||
RMAP CRC | ||||
CONFIG_SPW_RMAPCRC | ||||
Enable hardware calculation of the RMAP CRC checksum. RMAP CRC | ||||
is always enabled when the RMAP hardware target is enabled so this | ||||
parameter will have no effect in that case. | ||||
Rx unaligned | ||||
CONFIG_SPW_RXUNAL | ||||
Enable support for byte writes used for non word-aligned | ||||
receiver buffer addresses. Without this enabled data will | ||||
still be written at the correct location but complete words | ||||
will always be written so data outside the intended boundaries | ||||
might be overwritten. | ||||
Netlists | ||||
CONFIG_SPW_NETLIST | ||||
Use the netlist version of GRSPWC. This option is required if | ||||
you have not licensed the source code of the Spacewire core. | ||||
Currently only supported for Virtex and Axcelerator FPGAs. | ||||
The AHB/RX FIFO sizes should be set to 16 word/byte, and the | ||||
RMAP should be disabled. | ||||
Spacewire FT | ||||
CONFIG_SPW_FT | ||||
Say Y here to implement the Spacewire block rams with fault-tolerance | ||||
against SEU errors. | ||||
Spacewire core | ||||
CONFIG_SPW_GRSPW1 | ||||
Select to use GRSPW1 core or GRSPW2 core. | ||||
DMA channels | ||||
CONFIG_SPW_DMACHAN | ||||
Set the number of DMA channels for the GRSPW2 core | ||||
Ports | ||||
CONFIG_SPW_PORTS | ||||
Set the number of SpaceWire ports for the GRSPW2 core | ||||
Same clock for SpaceWire receiver and transmitter | ||||
CONFIG_SPW_RTSAME | ||||
Say Y here if the same clock is connected to both the receiver | ||||
and transmitter in the GRSPW2 core. This will remove two | ||||
asynchronous resets and some synchronization logic. This is only | ||||
applicable for the SDR and DDR inputs modes. | ||||
Receiver clock type | ||||
CONFIG_SPW_RX_SDR | ||||
Selects the input clocking scheme for the GRSPW2. SDR means that the | ||||
core samples data and strobe using single data rate registers at the | ||||
receiver clock frequency. DDR is the same except DDR registers are used. | ||||
Xor selects the traditional self clocking scheme using a xor gate. | ||||
Aeroflex sets the receiver in a mode compatible with the Aeroflex | ||||
SpaceWire transceiver. | ||||
Receiver clock type | ||||
CONFIG_SPW_TX_SDR | ||||
Selects the output clocking scheme for the GRSPW2. SDR means that the | ||||
core transmits data and strobe using single data rate registers at the | ||||
transmitter clock frequency. DDR is the same except DDR registers are used. | ||||
Aeroflex sets the transmitter in a mode compatible with the Aeroflex | ||||
SpaceWire transceiver. | ||||
UART1 enable | ||||
CONFIG_UART1_ENABLE | ||||
Say Y here to enable UART1, or the console UART. This is needed to | ||||
get any print-out from LEON3 systems regardless of operating system. | ||||
UART1 FIFO | ||||
CONFIG_UA1_FIFO1 | ||||
The UART has configurable transmitt and receive FIFO's, which can | ||||
be set to 1 - 32 bytes. Use 1 for minimum area, or 8 - 32 for | ||||
maximum throughput. | ||||
UART2 enable | ||||
CONFIG_UART2_ENABLE | ||||
Say Y here to enable UART2, or the secondary UART. This UART can be | ||||
used to connect a second console (uClinux) or to control external | ||||
equipment. | ||||
UART2 FIFO | ||||
CONFIG_UA2_FIFO1 | ||||
The UART has configurable transmitt and receive FIFO's, which can | ||||
be set to 1 - 32 bytes. Use 1 for minimum area, or 8 - 32 for | ||||
maximum throughput. | ||||
LEON3 interrupt controller | ||||
CONFIG_IRQ3_ENABLE | ||||
Say Y here to enable the LEON3 interrupt controller. This is needed | ||||
if you want to be able to receive interrupts. Operating systems like | ||||
Linux, RTEMS and eCos needs this option to be enabled. If you intend | ||||
to use the Bare-C run-time and not use interrupts, you could disable | ||||
the interrupt controller and save about 500 gates. | ||||
LEON3 interrupt controller broadcast | ||||
CONFIG_IRQ3_BROADCAST_ENABLE | ||||
If enabled the broadcast register is used to determine which | ||||
interrupt should be sent to all cpus instead of just the first | ||||
one that consumes it. | ||||
Secondary interrupts | ||||
CONFIG_IRQ3_SEC | ||||
The interrupt controller handles 15 interrupts by default (1 - 15). | ||||
These correspond to the 15 SPARC asyncronous traps (0x11 - 0x1F), | ||||
and AMBA interrupts 1 - 15. This option will enable 16 additional | ||||
(secondary) interrupts, corresponding to AMBA interrupts 16 - 31. | ||||
The secondary interrupts will be multiplexed onto one of the first | ||||
15 interrupts. The total number of handled interrupts can then | ||||
be up to 30 (14 primary and 16 secondary). | ||||
Number of interrupts | ||||
CONFIG_IRQ3_NSEC | ||||
Defines which of the first 15 interrupts should be used for the | ||||
secondary (16 - 31) interrupts. Interrupt 15 should be avoided | ||||
since it is not maskable by the processor. | ||||
Timer module enable | ||||
CONFIG_GPT_ENABLE | ||||
Say Y here to enable the Modular Timer Unit. The timer unit consists | ||||
of one common scaler and up to 7 independent timers. The timer unit | ||||
is needed for Linux, RTEMS, eCos and the Bare-C run-times. | ||||
Timer module enable | ||||
CONFIG_GPT_NTIM | ||||
Set the number of timers in the timer unit (1 - 7). | ||||
Scaler width | ||||
CONFIG_GPT_SW | ||||
Set the width if the common pre-scaler (2 - 16 bits). The scaler | ||||
is used to divide the system clock down to 1 MHz, so 8 bits should | ||||
be sufficient for most implementations (allows clocks up to 256 MHz). | ||||
Timer width | ||||
CONFIG_GPT_TW | ||||
Set the width if the timers (2 - 32 bits). 32 bits is recommended | ||||
for the Bare-C run-time, lower values (e.g. 16 bits) can work with | ||||
RTEMS and Linux. | ||||
Timer Interrupt | ||||
CONFIG_GPT_IRQ | ||||
Set the interrupt number for the first timer. Remaining timers will | ||||
have incrementing interrupts, unless the separate-interrupts option | ||||
below is disabled. | ||||
Watchdog enable | ||||
CONFIG_GPT_WDOGEN | ||||
Say Y here to enable the watchdog functionality in the timer unit. | ||||
Watchdog time-out value | ||||
CONFIG_GPT_WDOG | ||||
This value will be loaded in the watchdog timer at reset. | ||||
GPIO port | ||||
CONFIG_GRGPIO_ENABLE | ||||
Say Y here to enable a general purpose I/O port. The port can be | ||||
configured from 1 - 32 bits, whith each port signal individually | ||||
programmable as input or output. The port signals can also serve | ||||
as interrupt inputs. | ||||
GPIO port witdth | ||||
CONFIG_GRGPIO_WIDTH | ||||
Number of bits in the I/O port. Must be in the range of 1 - 32. | ||||
GPIO interrupt mask | ||||
CONFIG_GRGPIO_IMASK | ||||
The I/O port interrupt mask defines which bits in the I/O port | ||||
should be able to create an interrupt. | ||||
UART debugging | ||||
CONFIG_DEBUG_UART | ||||
During simulation, the output from the UARTs is printed on the | ||||
simulator console. Since the ratio between the system clock and | ||||
UART baud-rate is quite high, simulating UART output will be very | ||||
slow. If you say Y here, the UARTs will print a character as soon | ||||
as it is stored in the transmitter data register. The transmitter | ||||
ready flag will be permanently set, speeding up simulation. However, | ||||
the output on the UART tx line will be garbled. Has not impact on | ||||
synthesis, but will cause the LEON test bench to fail. | ||||
FPU register tracing | ||||
CONFIG_DEBUG_FPURF | ||||
If you say Y here, all writes to the floating-point unit register file | ||||
will be printed on the simulator console. | ||||