yosys/backends/cxxrtl/cxxrtl_capi.h

/*
 *  yosys -- Yosys Open SYnthesis Suite
 *
 *  Copyright (C) 2020  whitequark <whitequark@whitequark.org>
 *
 *  Permission to use, copy, modify, and/or distribute this software for any
 *  purpose with or without fee is hereby granted.
 *
 *  THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
 *  WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
 *  MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
 *  ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
 *  WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
 *  ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
 *  OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
 *
 */

#ifndef CXXRTL_CAPI_H
#define CXXRTL_CAPI_H

// This file is a part of the CXXRTL C API. It should be used together with `cxxrtl_capi.cc`.
//
// The CXXRTL C API makes it possible to drive CXXRTL designs using C or any other language that
// supports the C ABI, for example, Python. It does not provide a way to implement black boxes.

#include <stddef.h>
#include <stdint.h>

#ifdef __cplusplus
extern "C" {
#endif

// Opaque reference to a design toplevel.
//
// A design toplevel can only be used to create a design handle.
typedef struct _cxxrtl_toplevel *cxxrtl_toplevel;

// The constructor for a design toplevel is provided as a part of generated code for that design.
// Its prototype matches:
//
// cxxrtl_toplevel <design-name>_create();

// Opaque reference to a design handle.
//
// A design handle is required by all operations in the C API.
typedef struct _cxxrtl_handle *cxxrtl_handle;

// Create a design handle from a design toplevel.
//
// The `design` is consumed by this operation and cannot be used afterwards.
cxxrtl_handle cxxrtl_create(cxxrtl_toplevel design);

// Release all resources used by a design and its handle.
void cxxrtl_destroy(cxxrtl_handle handle);

// Simulate the design to a fixed point.
//
// Returns the number of delta cycles.
size_t cxxrtl_step(cxxrtl_handle handle);

// Type of a simulated object.
enum cxxrtl_type {
	// Values correspond to singly buffered netlist nodes, i.e. nodes driven exclusively by
	// combinatorial cells, or toplevel input nodes.
	//
	// Values can be inspected via the `curr` pointer. If the `next` pointer is NULL, the value is
	// driven by a constant and can never be modified. Otherwise, the value can be modified through
	// the `next` pointer (which is equal to `curr` if not NULL). Note that changes to the bits
	// driven by combinatorial cells will be ignored.
	//
	// Values always have depth 1.
	CXXRTL_VALUE = 0,

	// Wires correspond to doubly buffered netlist nodes, i.e. nodes driven, at least in part, by
	// storage cells, or by combinatorial cells that are a part of a feedback path.
	//
	// Wires can be inspected via the `curr` pointer and modified via the `next` pointer (which are
	// distinct for wires). Note that changes to the bits driven by combinatorial cells will be
	// ignored.
	//
	// Wires always have depth 1.
	CXXRTL_WIRE = 1,

	// Memories correspond to memory cells.
	//
	// Memories can be inspected and modified via the `curr` pointer. Due to a limitation of this
	// API, memories cannot yet be modified in a guaranteed race-free way, and the `next` pointer is
	// always NULL.
	CXXRTL_MEMORY = 2,

	// More object types will be added in the future, but the existing ones will never change.
};

// Description of a simulated object.
//
// The `data` array can be accessed directly to inspect and, if applicable, modify the bits
// stored in the object.
struct cxxrtl_object {
	// Type of the object.
	//
	// All objects have the same memory layout determined by `width` and `depth`, but the type
	// determines all other properties of the object.
	uint32_t type; // actually `enum cxxrtl_type`

	// Width of the object in bits.
	size_t width;

	// Depth of the object. Only meaningful for memories; for other objects, always 1.
	size_t depth;

	// Bits stored in the object, as 32-bit chunks, least significant bits first.
	//
	// The width is rounded up to a multiple of 32; the padding bits are always set to 0 by
	// the simulation code, and must be always written as 0 when modified by user code.
	// In memories, every element is stored contiguously. Therefore, the total number of chunks
	// in any object is `((width + 31) / 32) * depth`.
	//
	// To allow the simulation to be partitioned into multiple independent units communicating
	// through wires, the bits are double buffered. To avoid race conditions, user code should
	// always read from `curr` and write to `next`. The `curr` pointer is always valid; for objects
	// that cannot be modified, or cannot be modified in a race-free way, `next` is NULL.
	uint32_t *curr;
	uint32_t *next;

	// More description fields will be added in the future, but the existing ones will never change.
};

// Retrieve description of a simulated object.
//
// The `name` is the full hierarchical name of the object in the Yosys notation, where public names
// have a `\` prefix and hierarchy levels are separated by single spaces. For example, if
// the top-level module instantiates a module `foo`, which in turn contains a wire `bar`, the full
// hierarchical name is `\foo \bar`.
//
// Returns the object if it was found, NULL otherwise. The returned value is valid until the design
// is destroyed.
struct cxxrtl_object *cxxrtl_get(cxxrtl_handle handle, const char *name);

// Enumerate simulated objects.
//
// For every object in the simulation, `callback` is called with the provided `data`, the full
// hierarchical name of the object (see `cxxrtl_get` for details), and the object description.
// The provided `name` and `object` values are valid until the design is destroyed.
void cxxrtl_enum(cxxrtl_handle handle, void *data,
                 void (*callback)(void *data, const char *name, struct cxxrtl_object *object));

#ifdef __cplusplus
}
#endif

#endif
cxxrtl: add a C API for driving and introspecting designs. Compared to the C++ API, the C API currently has two limitations: 1. Memories cannot be updated in a race-free way. 2. Black boxes cannot be implemented in C. 2020-06-05 08:52:30 -05:00			`/*`
			`* yosys -- Yosys Open SYnthesis Suite`
			`*`
			`* Copyright (C) 2020 whitequark <whitequark@whitequark.org>`
			`*`
			`* Permission to use, copy, modify, and/or distribute this software for any`
			`* purpose with or without fee is hereby granted.`
			`*`
			`* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES`
			`* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF`
			`* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR`
			`* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES`
			`* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN`
			`* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF`
			`* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.`
			`*`
			`*/`

			`#ifndef CXXRTL_CAPI_H`
			`#define CXXRTL_CAPI_H`

			// This file is a part of the CXXRTL C API. It should be used together with `cxxrtl_capi.cc`.
			`//`
			`// The CXXRTL C API makes it possible to drive CXXRTL designs using C or any other language that`
			`// supports the C ABI, for example, Python. It does not provide a way to implement black boxes.`

			`#include <stddef.h>`
			`#include <stdint.h>`

			`#ifdef __cplusplus`
			`extern "C" {`
			`#endif`

			`// Opaque reference to a design toplevel.`
			`//`
			`// A design toplevel can only be used to create a design handle.`
			`typedef struct _cxxrtl_toplevel *cxxrtl_toplevel;`

			`// The constructor for a design toplevel is provided as a part of generated code for that design.`
			`// Its prototype matches:`
			`//`
			`// cxxrtl_toplevel <design-name>_create();`

			`// Opaque reference to a design handle.`
			`//`
			`// A design handle is required by all operations in the C API.`
			`typedef struct _cxxrtl_handle *cxxrtl_handle;`

			`// Create a design handle from a design toplevel.`
			`//`
			// The `design` is consumed by this operation and cannot be used afterwards.
			`cxxrtl_handle cxxrtl_create(cxxrtl_toplevel design);`

			`// Release all resources used by a design and its handle.`
			`void cxxrtl_destroy(cxxrtl_handle handle);`

			`// Simulate the design to a fixed point.`
			`//`
			`// Returns the number of delta cycles.`
			`size_t cxxrtl_step(cxxrtl_handle handle);`

			`// Type of a simulated object.`
			`enum cxxrtl_type {`
			`// Values correspond to singly buffered netlist nodes, i.e. nodes driven exclusively by`
			`// combinatorial cells, or toplevel input nodes.`
			`//`
cxxrtl: emit debug information for constant wires. Constant wires can represent a significant chunk of the design in generic designs or after optimization. Emitting them in VCD files significantly improves usability because gtkwave removes all traces that are not present in the VCD file after reload, and iterative development suffers if switching a varying signal to a constant disrupts the workflow. 2020-06-08 12:29:08 -05:00			// Values can be inspected via the `curr` pointer. If the `next` pointer is NULL, the value is
			`// driven by a constant and can never be modified. Otherwise, the value can be modified through`
			// the `next` pointer (which is equal to `curr` if not NULL). Note that changes to the bits
			`// driven by combinatorial cells will be ignored.`
cxxrtl: add a C API for driving and introspecting designs. Compared to the C++ API, the C API currently has two limitations: 1. Memories cannot be updated in a race-free way. 2. Black boxes cannot be implemented in C. 2020-06-05 08:52:30 -05:00			`//`
			`// Values always have depth 1.`
			`CXXRTL_VALUE = 0,`

			`// Wires correspond to doubly buffered netlist nodes, i.e. nodes driven, at least in part, by`
			`// storage cells, or by combinatorial cells that are a part of a feedback path.`
			`//`
			// Wires can be inspected via the `curr` pointer and modified via the `next` pointer (which are
cxxrtl: emit debug information for constant wires. Constant wires can represent a significant chunk of the design in generic designs or after optimization. Emitting them in VCD files significantly improves usability because gtkwave removes all traces that are not present in the VCD file after reload, and iterative development suffers if switching a varying signal to a constant disrupts the workflow. 2020-06-08 12:29:08 -05:00			`// distinct for wires). Note that changes to the bits driven by combinatorial cells will be`
			`// ignored.`
cxxrtl: add a C API for driving and introspecting designs. Compared to the C++ API, the C API currently has two limitations: 1. Memories cannot be updated in a race-free way. 2. Black boxes cannot be implemented in C. 2020-06-05 08:52:30 -05:00			`//`
			`// Wires always have depth 1.`
			`CXXRTL_WIRE = 1,`

			`// Memories correspond to memory cells.`
			`//`
			// Memories can be inspected and modified via the `curr` pointer. Due to a limitation of this
			// API, memories cannot yet be modified in a guaranteed race-free way, and the `next` pointer is
			`// always NULL.`
			`CXXRTL_MEMORY = 2,`

			`// More object types will be added in the future, but the existing ones will never change.`
			`};`

			`// Description of a simulated object.`
			`//`
			// The `data` array can be accessed directly to inspect and, if applicable, modify the bits
			`// stored in the object.`
			`struct cxxrtl_object {`
			`// Type of the object.`
			`//`
			// All objects have the same memory layout determined by `width` and `depth`, but the type
			`// determines all other properties of the object.`
			uint32_t type; // actually `enum cxxrtl_type`

			`// Width of the object in bits.`
			`size_t width;`

			`// Depth of the object. Only meaningful for memories; for other objects, always 1.`
			`size_t depth;`

			`// Bits stored in the object, as 32-bit chunks, least significant bits first.`
			`//`
			`// The width is rounded up to a multiple of 32; the padding bits are always set to 0 by`
			`// the simulation code, and must be always written as 0 when modified by user code.`
			`// In memories, every element is stored contiguously. Therefore, the total number of chunks`
			// in any object is `((width + 31) / 32) * depth`.
			`//`
			`// To allow the simulation to be partitioned into multiple independent units communicating`
			`// through wires, the bits are double buffered. To avoid race conditions, user code should`
			// always read from `curr` and write to `next`. The `curr` pointer is always valid; for objects
			// that cannot be modified, or cannot be modified in a race-free way, `next` is NULL.
			`uint32_t *curr;`
			`uint32_t *next;`

			`// More description fields will be added in the future, but the existing ones will never change.`
			`};`

			`// Retrieve description of a simulated object.`
			`//`
			// The `name` is the full hierarchical name of the object in the Yosys notation, where public names
			// have a `\` prefix and hierarchy levels are separated by single spaces. For example, if
			// the top-level module instantiates a module `foo`, which in turn contains a wire `bar`, the full
			// hierarchical name is `\foo \bar`.
			`//`
			`// Returns the object if it was found, NULL otherwise. The returned value is valid until the design`
			`// is destroyed.`
			`struct cxxrtl_object cxxrtl_get(cxxrtl_handle handle, const char name);`

			`// Enumerate simulated objects.`
			`//`
			// For every object in the simulation, `callback` is called with the provided `data`, the full
			// hierarchical name of the object (see `cxxrtl_get` for details), and the object description.
			// The provided `name` and `object` values are valid until the design is destroyed.
			`void cxxrtl_enum(cxxrtl_handle handle, void *data,`
			`void (callback)(void data, const char name, struct cxxrtl_object object));`

			`#ifdef __cplusplus`
			`}`
			`#endif`

			`#endif`